Download The role of funding and policies on cancer drugs (report)

THE ROLE OF FUNDING AND POLICIES ON
INNOVATION IN CANCER DRUG
DEVELOPMENT
Panos Kanavos
Richard Sullivan
Grant Lewison
Willemien Schurer
Seth Eckhouse
Zefi Vlachopioti
September 2009
THE AUTHORS
Panos Kanavos, PhD, is Senior Lecturer in International Health Policy in the Department of
Social Policy and LSE Health, London School of Economics.
Richard Sullivan, MD, PhD, is Chairman of the European Cancer Research Managers Forum
(ECRM).
Grant Lewison, PhD, is MD Evaluametrics Ltd.
Willemien Schurer, MSc, is Research Officer at LSE Health, London School of Economics.
Seth Eckhouse is Chief Projects Officer at ECRM.
Zefi Vlachopioti, MSc, is Research Assistant at LSE Health, London School of Economics.
ACKNOWLEDGEMENT
This report was funded by an unrestricted educational grant from Novartis Pharma AG.
© Panos Kanavos, Richard Sullivan, Grant Lewison, Willemien Schurer, Seth Eckhouse, Zefi
Vlachopioti, 2009.
Table of Contents
THE ROLE OF FUNDING AND POLICIES ON INNOVATION IN CANCER DRUG
DEVELOPMENT
i
Table of Contents
i
List of Tables and Figures
vi
List of Abbreviations
x
List of Abbreviations
x
EXECUTIVE SUMMARY
xiii
Results: Funding, Bibliometric Outputs and Faculty Survey
xiii
Funding
xiii
Bibliometric analysis
xiv
Survey of oncology faculty
xiv
Policy Implications: Funding, Bibliometric Outputs and Faculty Survey
xv
Fostering Oncology Innovation
xvi
National and supra-national roles in innovation
xvi
The uniqueness of rare cancers
xvii
Role of the reimbursement system
xvii
Risk sharing
xvii
Continuous evaluation of oncology drugs
xvii
Optimizing resource allocation in health care
xviii
Conclusions
xviii
1. BACKGROUND AND OBJECTIVES
1
1. 1. The Burden of Cancer
1
1.1.1 Risk Factors, Incidence and Mortality
1
1.1.2 Prevalence and Direct/ Indirect Costs
2
1.1.3 Advancement in Cancer Medical Treatments
3
1.2. The R&D process
4
1.2.1 General Trends
4
1.2.2 Cancer R&D
5
i
1.3. Trends in R&D spending and output by the private sector
7
1.3.1 Aggregate R&D trends in pharmaceutical and biotechnology industries
7
1.3.2 Cancer R&D Trends
9
1.4. Aim of this report
10
References
13
2. THE HISTORY AND SCIENCE OF CANCER DRUG DEVELOPMENT
15
2.1. A European History of Cancer Research
15
2.2. New Paradigms in Chemotherapy
19
2.3. Attacking Cancer
20
2.4. Biologicals for Cancer Therapy
25
2.5. Concluding Remarks
30
References
32
3. PUBLIC AND PRIVATE FUNDING FOR CANCER DRUG RESEARCH AND DEVELOPMENT
34
3.1. Background and objectives
34
3.2. Methods
37
3.2.1. Surveying public sector spending on cancer drug research and development
37
3.2.2. Private sector contribution
39
3.3. Findings
39
3.3.1. Public (non-commercial) funding
40
3.3.2. Private sector cancer funding organisations
74
3.3.3. Public – Private partnerships in cancer drug development
77
3.4. Discussion
78
3.4.1. Public Sector Funding
79
3.4.2. Private sector funding
90
3.4.3. PPPs in cancer drug development
93
3.5. Concluding remarks
95
References
97
4. RESEARCH ACTIVITY IN DRUG DEVELOPMENT: A BIBLIOMETRIC ANALYSIS
101
4.1. Background and Objectives
101
4.2. Methods
103
4.2.1. Focus of study
103
4.2.2. Selection of papers
105
ii
4.2.3. Comparison with outputs of all cancer research and all drugs
106
4.2.4. Research Levels
110
4.2.5. Geographical Analysis
110
4.2.6. Cancer Manifestations and Disease Burden
111
4.2.7. Funding of Cancer Drug Research
111
4.3. Results
114
4.3.1. Volume of cancer drug paper outputs
114
4.3.2. National involvement in cancer drug research
117
4.3.3. Site specific research in cancer drug research
124
4.3.4. Clinical versus basic cancer research types
131
4.3.5. Trends in global and regional cancer drug development
137
4.3.6. Funding of cancer drug research
140
4.4. Conclusions and Policy Issues
151
4.4.1. Policy Conclusions
152
References
156
5. PROMOTING AND SUPPORTING CANCER DRUG R&D – RESULTS OF A SENIOR
SCIENTISTS SURVEY
157
5.1. Background and Objectives
157
5.2. Methodological Approach
158
5.2.1. Semi-Structured Interviews
158
5.2.2. Faculty: Inclusion Criteria and Demographics
158
5.2.3. Questionnaire Development
159
5.2.4. Questionnaire Analysis
160
5.3. Results of the clinician and scientist survey
161
5.3.1. Interviews with drug development faculty
161
5.3.2. Results of the survey of European and USA key opinion leaders
169
5.4. Discussion and policy implications
182
5.4.1. Public-Private Partnership Models
182
5.4.2. Investing in Cancer Drug Development
184
5.4.3. Environment for cancer drug development
185
References
187
6. SUPPORTING AND ENABLING INNOVATION IN ONCOLOGY: ISSUES IN PUBLIC
POLICY
189
6.1. Background and Objectives
189
6.2. Data and methods
190
iii
6.3. Contribution of pharmaceutical innovation to health and well being
191
6.3.1. What is innovation?
191
6.3.2. Impact of pharmaceutical innovation on health
192
6.4. Is health care and pharmaceutical innovation worthwhile?
194
6.4.1. Therapeutic/clinical benefits
195
6.4.2. Socio-economic benefits
198
6.5. Different approaches to valuing pharmaceutical innovation in Europe
204
6.5.1. Valuing innovation in the context of drug reimbursement
204
6.5.2. Rate of return regulation
206
6.5.3. Assessment of clinical/therapeutic benefit
208
6.5.4. Health Technology Assessment in assessing value of innovation
211
6.5.5. Role of European institutions
214
6.6. Fostering innovation in oncology: A list of priorities
216
6.6.1. The role of national and supra-national science, research and innovation policy
216
6.6.2. Need for pricing and reimbursement systems to reward and encourage innovation
220
6.6.3. Continuous evaluation of oncology drugs
225
6.6.4. Encouraging long-term innovation
226
6.6.5. Optimizing resource allocation in health care
227
6.7. Concluding remarks
230
References
231
7. CONCLUSIONS AND POLICY IMPLICATIONS
235
7.1. Introduction
235
7.2. Funding
236
7.2.1 Results of public and private research funding organisations survey
236
7.2.2 Policy implications
238
7.3 Capturing investment in oncology through research outputs
239
7.3.1. Results of the bibliometric survey on oncology research output
240
7.3.2. Policy implications
240
7.4 Public Policy in Oncology Development
241
7.4.1. Results of our public policy survey of oncology clinicians
241
7.4.2. Policy implications
242
7.5. Fostering innovation in oncology: A list of priorities
243
7.5.1. The role of national and supra-national science, research and innovation policy
244
7.5.2. Encouraging and rewarding innovation through the reimbursement system
247
7.5.3. Risk sharing
248
7.5.4. Minimising (negative) externalities
249
iv
7.5.5. Continuous evaluation of oncology drugs
249
7.5.6. Optimizing resource allocation in health care
250
References
251
Reference List
252
v
List of Tables and Figures
1. Background and Objectives
Table 1.1................................................................................................................................................................. 2
Global cancer related deaths and burden of disease by sex (2004) ..................................................................... 2
Figure 1.1 ............................................................................................................................................................... 3
Cancer related deaths and burden of disease grouped by income per capita (2004) ......................................... 3
Source: World Health Organisation, The Global Burden of Disease: 2004 update. WHO 2008. ......................... 3
Figure 1.2 ............................................................................................................................................................... 8
Global R&D expenditure, development times, NME output and global pharmaceutical sales (1997-2007) ...... 8
Notes: Each trend line has been indexed to 1997 values........................................................................................ 8
Development time data point for 2007 includes data from 2006 and 2007 only .................................................... 8
Source: CMR International & IMS Health............................................................................................................. 8
Figure 1.3 ............................................................................................................................................................... 9
Number* of new cancer drugs in development by type of cancer ........................................................................ 9
Figure 3.1 ............................................................................................................................................................. 35
The public-private interface in cancer drug research and development........................................................... 35
Figure 3.2 ............................................................................................................................................................. 43
Number of public sector funding organizations by country............................................................................... 43
Table 3.1............................................................................................................................................................... 53
Synopsis of policies and programmes encouraging cancer drug development globally................................... 53
Figure 3.3 ............................................................................................................................................................. 59
Direct cancer drug R&D (Spending on log scale) ............................................................................................... 59
Table 3.2............................................................................................................................................................... 59
Drug R&D as percentage of total direct spending .............................................................................................. 59
Figure 3.4 ............................................................................................................................................................. 60
Estimated indirect cancer R&D funding ............................................................................................................. 60
Figure 3.5 ............................................................................................................................................................. 61
Cancer R&D direct spending (€) per capita........................................................................................................ 61
Table 3.3............................................................................................................................................................... 61
Top-10 public spenders on cancer R&D per capita vs. absolute spending......................................................... 61
Table 3.4............................................................................................................................................................... 62
Top-10 public spenders on cancer drug R&D per capita vs. absolute spend ..................................................... 62
Table 3.5............................................................................................................................................................... 63
Main funding sources of Europe’s top funding countries (public sector) .......................................................... 63
Figure 3.6 ............................................................................................................................................................. 64
vi
Direct cancer R&D spending per capita, 2004 vs. 2007 (€) ............................................................................... 64
Figure 3.7 ............................................................................................................................................................. 65
Cancer drug R&D and cancer R&D direct spending, % of GDP .......................................................................... 65
Figure 3.8 ............................................................................................................................................................. 66
Route of cancer drug R&D funding ..................................................................................................................... 66
Figure 3.9 ............................................................................................................................................................. 67
Cancer drug R&D spend per capita (€) ............................................................................................................... 67
Figure 3.10 ........................................................................................................................................................... 67
Cancer drug R&D spend, % of GDP...................................................................................................................... 67
Figure 3.11 ........................................................................................................................................................... 69
European cancer R&D spend by CSO category ................................................................................................... 69
Figure 3.12 ........................................................................................................................................................... 70
Number of active cancer drug development projects by funder, grouped by country (log scale) .................... 70
Figure 3.13 ........................................................................................................................................................... 71
Scatter plot showing percentage of spend according to domain of research (by CSO category) for a sample of
European Cancer Centres (n= 20) ....................................................................................................................... 71
Figure 3.14 ........................................................................................................................................................... 73
Drug R&D funding by charities and government (2007) ................................................................................... 73
Figure 3.15 ........................................................................................................................................................... 74
Percent of direct spend by political group in Europe (2007) ............................................................................. 74
Figure 3.16 ........................................................................................................................................................... 76
Private cancer drug development spend: major pharmaceutical companies (2004/ Phase III)* .................... 76
Figure 3.17 ........................................................................................................................................................... 77
Private cancer R&D funding by company origin ................................................................................................ 77
Figure 3.18 ........................................................................................................................................................... 78
Cancer drug development projects with joint private-public funding (%) (2007-8) ........................................ 78
Figure 3.19 ........................................................................................................................................................... 82
Interaction between basic vs applied science and between market vs government ......................................... 82
Table 4.1............................................................................................................................................................. 104
Major 19 selected cancer drugs used for data collection ................................................................................. 104
Table 4.2............................................................................................................................................................. 105
List of all drugs listed as being approved for cancer treatment (2009).............................................................. 105
Table 4.3............................................................................................................................................................. 107
Estimated total disease burden (DALYs) and cancer burden (DALYs, %) in 15 countries (2004).................. 107
Table 4.4............................................................................................................................................................. 108
Main 16 cancer sites, disease burdens (DALYs) and mortality rates (2004) ................................................... 108
Table 4.5............................................................................................................................................................. 109
Ratios of relative disease burden (DALYs) for 16 cancer sites to global average in 15 countries .................. 109
Table 4.6............................................................................................................................................................. 112
vii
Pharmaceutical companies involved in 19 cancer drugs: trigraph identifying codes, search strings and drug
codes................................................................................................................................................................... 113
Figure 4.1 ........................................................................................................................................................... 114
Total WoS output for 19 cancer drug research papers (3-year running means) (1970- 2007) ..................... 114
Figure 4.2 ........................................................................................................................................................... 115
Proportion of total drug (blue) and 19 drugs (red) cancer research papers of total cancer research papers
............................................................................................................................................................................ 115
Figure 4.3 ........................................................................................................................................................... 115
WoS cancer drug papers for 19 cancer drugs (1963-2009)............................................................................. 115
Figure 4.4 ........................................................................................................................................................... 116
Distribution of papers in 15 countries (integer, fractional counts) ................................................................. 116
Table 4.7............................................................................................................................................................. 116
Publication languages in cancer drug research papers (1963-2009) ............................................................. 116
Table 4.8............................................................................................................................................................. 119
Matrix of total cancer research papers per country to the 19 selected cancer drug papers per country
(fractional counts) ............................................................................................................................................. 119
Table 4.9 ............................................................................................................................................................. 120
Matrix of ratios of observed to expected cancer drug research papers per country ....................................... 120
Table 4.10........................................................................................................................................................... 122
Cancer drug paper ouputs in 15 countries for 19 selected drugs (fractional counts)..................................... 122
Table 4.11........................................................................................................................................................... 123
Relative research concentration of the 15 countries for 19 selected drugs (1963-2009) ............................... 123
Table 4.12........................................................................................................................................................... 124
Global cancer drug research in 15 countries for all drugs (ALL) and 19 selected cancer drugs (19D) (%,
integer counts) (1994-2008) ............................................................................................................................. 124
Table 4.13........................................................................................................................................................... 125
Research paper outputs: 19 cancer drugs per top 16 cancer sites (1963-2009)............................................. 125
Table 4.14........................................................................................................................................................... 126
Cancer drug research outputs in 16 cancer sites for all drugs (ALL) and 19 selected drugs (19 D) (19842008) .................................................................................................................................................................. 126
Figure 4.5 ........................................................................................................................................................... 127
Cancer drug paper outputs (1994-2008) versus cancer burden of disease (% DALYs) (2004) (weighted by the
countries’ presence in cancer drug research) ................................................................................................... 127
Table 4.15........................................................................................................................................................... 128
Numbers of cancer papers (fractional counts) for the 15 leading countries for 19 selected drugs in 16 cancer
sites..................................................................................................................................................................... 128
Table 4.16........................................................................................................................................................... 129
Ratios of observed to expected cancer drug research paper outputs for 15 countries for 16 cancer sites..... 129
Figure 4.6 ........................................................................................................................................................... 130
Country specific correlation coefficient of cancer drug paper outputs versus burden for 16 cancer sites..... 130
viii
Figure 4.7 ........................................................................................................................................................... 131
China: cancer drug research output versus burden from 16 cancer sites........................................................ 131
Figure 4.8 ........................................................................................................................................................... 132
Mean research level (RL) of all cancer drug papers in five quintiles ............................................................... 132
Figure 4.9 ........................................................................................................................................................... 133
Mean research level (RL): journal source (RLj) versus title source (RLp) in 19 cancer drug papers (1963 2009) .................................................................................................................................................................. 133
Figure 4.10 ......................................................................................................................................................... 134
Average research level (RL) per time quintile for 6 cancer drugs ................................................................... 134
Figure 4.11 ......................................................................................................................................................... 134
Mean research level (RL) from 15 countries in 19 cancer drug research papers per paper title (paper) and
per journal source (journal) .............................................................................................................................. 134
Figure 4.12 ......................................................................................................................................................... 135
Phased carboplatin clinical trials longitudinal paper outputs (3-year running means) ................................ 135
Table 4.17........................................................................................................................................................... 136
Phased clinical trials paper outputs in 19 cancer drugs (1963 -2009)............................................................ 136
Figure 4.13 ......................................................................................................................................................... 137
Percentage cancer drug clinical trials output per mean research level in 15 countries................................. 137
Figure 4.14 ......................................................................................................................................................... 138
Geographical distribution of cancer drug papers in three world regions (USA, EUR 30, RoW) (quintiles,
fractional counts) (1963-2009)......................................................................................................................... 138
Figure 4.15 ......................................................................................................................................................... 138
Chinese cancer drug papers, 3-year running means (fractional counts) (1996-2008)................................... 138
Figure 4.16 ......................................................................................................................................................... 139
Distribution of 19 cancer drug papers by geographical region: USA, EUR30 and RoW (fractional counts).. 139
Table 4.18........................................................................................................................................................... 140
Global percentage of 10 RoW countries in 19 cancer drug papers (fractional counts) (1980-2009) ........... 140
Table 4.19........................................................................................................................................................... 141
Intramural papers in 19 cancer drugs per phama company (1963-2009) ..................................................... 141
Table 4.20........................................................................................................................................................... 141
Pre- and post- marketing approval paper output in 19 cancer drugs by their developing pharmaceutical
company versus other companies ..................................................................................................................... 141
Table 4.21........................................................................................................................................................... 143
Funding sources in 19 selected cancer drug papers (1963-2009) ................................................................... 143
Figure 4.17 ......................................................................................................................................................... 144
Funding sources in 19 cancer drug papers (1963-2009) ................................................................................. 144
Figure 4.18 ......................................................................................................................................................... 144
Funding sources for 6 out of 19 cancer drugs* in different time quintiles....................................................... 144
Figure 4.19 ......................................................................................................................................................... 145
Funding sources for cancer drug papers in 15 leading countries (1963-2009) .............................................. 145
ix
Table 4.22........................................................................................................................................................... 146
Funding sources for cancer drug papers in 15 countries: Ratio of percent of national papers to world mean
(1963-2009) ....................................................................................................................................................... 146
Table 4.23........................................................................................................................................................... 148
Funding sources for cancer drug research papers in 16 cancer manifestations (1963-2009) ....................... 148
Table 4.24........................................................................................................................................................... 149
Governmental organisations supporting cancer drug research (1963-2009) ................................................ 149
Table 4.25........................................................................................................................................................... 150
Non-profit organisations supporting cancer drug research (1963-2009) ...................................................... 150
Table 5.1............................................................................................................................................................. 168
Strengths, weaknesses, opportunities and threats for public cancer drug development ................................ 168
Figure 5.1 ........................................................................................................................................................... 170
“Is private sector support for drug development essential?”............................................................................ 170
Figure 5.2 ........................................................................................................................................................... 171
“Is the current level of national public sector investment adequate?”............................................................. 171
Figure 5.3 ........................................................................................................................................................... 171
“Does the public sector have a limited role in cancer drug development?” ..................................................... 171
Figure 5.4 ........................................................................................................................................................... 173
“How important is the intellectual (academic faculty) environment?” ........................................................... 173
Figure 5.5 ........................................................................................................................................................... 174
“Are financial incentives important for public-private partnerships?” ........................................................... 174
Figure 5.6 ........................................................................................................................................................... 174
“Should private sector support be short term project based?”......................................................................... 174
Figure 5.7 ........................................................................................................................................................... 175
“Should nationalisation of parts of the drug development process be considered?”....................................... 175
Figure 5.8 ........................................................................................................................................................... 176
“Is the balance between private and public cancer drug development correct?” ........................................... 176
Figure 5.9 ........................................................................................................................................................... 177
“Is the regulatory environment a key area for success?”.................................................................................. 177
Figure 5.10 ......................................................................................................................................................... 178
“How important are policies around the reimbursement of new cancer drugs to future success?” ............... 178
Figure 5.11 ......................................................................................................................................................... 178
“How important are supra-national funding initiatives?” ............................................................................... 178
Figure 5.12 ......................................................................................................................................................... 179
“How important are national funding policies from research funding organisations?”................................. 179
Figure 5.13 ......................................................................................................................................................... 180
“Is institutional support important for success in cancer drug discovery?” .................................................... 180
Figure 5.14 ......................................................................................................................................................... 180
“Are technology transfer and / or incentive schemes important policy areas?” ............................................. 180
Figure 5.15 ......................................................................................................................................................... 181
x
“Are new models in PPP are needed?” ............................................................................................................... 181
Figure 5.16 ......................................................................................................................................................... 182
“New models for R&D in cancer drug discovery and development are needed”.............................................. 182
Table 6.1............................................................................................................................................................. 199
The six economic categories for innovative medicines ..................................................................................... 199
Table 6.2............................................................................................................................................................. 205
Criteria for assessing new technologies in 15 EU countries (2009) ................................................................. 205
Table 6.3............................................................................................................................................................. 208
ASMR categories in France ................................................................................................................................ 208
Table 6.4............................................................................................................................................................. 209
The IAA algorithm.............................................................................................................................................. 209
Figure 6.1 ........................................................................................................................................................... 210
Assessing therapeutic innovation in Italy ......................................................................................................... 210
Table 6.5............................................................................................................................................................. 214
Institutions and advisory bodies responsible for HTA activities in selected EU countries (2008) .................. 214
Table 6.6............................................................................................................................................................. 215
The benefits of pharmaceutical innovation1 ..................................................................................................... 215
Table 6.7............................................................................................................................................................. 229
Generic policies, savings foregone and impact on stakeholders, 2003-2004, seven countries1 (based on five
off-patent molecules2)........................................................................................................................................ 229
xi
List of Abbreviations
ABPI
ACI
ACS
AHCPR
AICR
ASMR
BBSRC
BCG
CCLG
CCRA
CDC
CML
CMR
CRADA
CRUK
CSC
CSO
DALYs
DC
DCE-MRI
DHHS
DNA
DOD
DOE
DoH
EC
ECMC
EDCTP
EFPIA
EFRR
EFTA
EMEA
EPA
ESRC
EU
FDA
FECS
FP
GAVI
GDP
GFATM
Association of British Pharmaceutical Industry (UK)
Actual citation impact
American Cancer Society (USA)
Agency for Healthcare Research and Quality (USA)
American Institute for Cancer Research (USA)
Amelioration du Service Medical Rendu (France)
Biotechnology and Biological Sciences Research Council (UK)
Bacillus Calmette-Guerin
Children’s Cancer and Leukaemia Group
Canadian Cancer Research Alliance (Canada)
Centers for Disease Control and Prevention (USA)
Chronic myeloid leukaemia
Centre for Medicines Research
Cooperative research and development agreements
Cancer Research UK (UK)
Cancer stem cells
Common Scientific Outcome
Disability adjusted life years
Dendritic cell
Magnetic resonance imaging
Department of Health and Human Services Agencies (USA)
Deoxyribonucleic acid
Department of Defense (USA)
Department of Energy (USA)
Department of Health (UK)
European Commission
Experimental Cancer Medicine Centres
European and Developing Countries Clinical Trials Partnership
European Federation of Pharmaceutical Industries and Associations
Epidermal growth factor receptor
European Free Trade Association
European Medicines Agency
Environmental Protection Agency (USA)
Economic and Social Research Council (UK)
European Union
US Food and Drug Administration (USA)
Federation of European Cancer Societies
Framework Programme
Global Alliance for Vaccines and Immunisations
Gross Domestic Product
Global Fund to Fight AIDS, Tuberculosis and Malaria
xii
GMP
HBV
HCFA
HER2
HIV
HPV
ICR
ICRP
IFN-α/γ
IL-2
IMI
INCA
IOM
IOM
IPR
IPR
ITCC
JPMA
MA
MAb
MDR
MEPS
MRC
NASA
NCE
NCI
NCRI
NDA
NGO
NHS
NIH
NK
NME
NSCLC
NSF
P CG
P GOV
P MED
P TB
PCI
PET
PhRMA
PIP
PR
QA
QC
Good manufacturing process
Hepatitis B
Health Care Financing Administration (USA)
Human epidermal growth factor receptor 2
Human immunodeficiency virus
Human papilloma virus
Initial Cancer Research Partners
International Cancer Research Portfolio
Interferon, alpha/gamma
Interleukin-2
International Medicines Initiative
Institut National du Cancer (France)
Institute of Medicine
Institute of Medicine (USA)
Intellectual property rights
Intellectual property rights
Innovative Therapies for Children with Cancer
Japan Pharmaceutical Manufacturers Association
Market Authorisation
Monoclonal antibodies
Multi-drug resistance
US Medical Expenditure Panel (USA)
Medical Research Council (UK)
National Agency for Space Exploration (USA)
New chemical entity
National Cancer Institute (USA)
National Cancer Research Institute (UK)
New drug applications
Non governmental organisations
National Health Service (UK)
National Institute of Health (NIH)
Natural killer
New molecular entity
Non-small cell lung cancer
National Science Foundation (USA)
% of papers on clinical guidelines
% of papers on government policy
% of papers in mass media
% of papers in text-books
Potential citation impact
Positron emission tomography
Pharmaceutical Research and Manufacturers of America
Paediatric investigation plan
% of reviews
Quality assurance
Quality control
xiii
R&D
RaDiUS
RFO
RL j
RL p
RNA
ROI
RoW
SENDO
SFOP
SIOPE
SmPC
SPC
SSRI
SWOT
TCA
TILs
TNF-α
TRAP
UJ
USA
USDA
USTPO
VA
VEGF
WHO
WoS
Research and Development
RAND Corporation’s Research and Development in the US database
Research funding organisations
Research level journals
Research level titles
Ribonucleic acid
Return on investment
Rest of world
Southern Europe New Drug Organisation
French Society of Paediatric Oncology
International Society of Paediatric Oncology
Summary of Product Characteristics
Supplementary protection certificate
Serotonin re-uptake inhibitors
Strengths, Weaknesses, Opportunities and Threats
Tricyclic anti-depressants
Tumour infiltrating lymphocytes
Tumour necrosis factor, alpha
Target related affinity profiling
Utility of journals
United States of America
US Department of Agriculture (USA)
US Patent and Trademark Office (USA)
Department for Veterns’ Affairs (USA)
Vascular endothelial growth factor
World Health Organisation
Web of Science
xiv
EXECUTIVE SUMMARY
During the past two decades, cancer incidence has steadily increased due to aging
populations, lifestyle and environmental factors, with great personal and national
economic consequences. Concurrently, cancer treatments have improved with
increased treatment options as well as lengthier disease and disease-free survival rates.
The latest innovation in cancer treatments are targeted biological treatments, joining
the current arsenal of surgery, radiotherapy and chemotherapy, particularly significant
in latter stage cancers associated with very poor survival.
Despite this latest breakthrough in cancer treatment, this has in fact only opened the
door to beginning to understand the complexity of cancer on a molecular and genetic
basis. Oncology research and development (R&D) has the highest failure rate for new
molecular entities (NME) and significantly higher development costs. Although
tremendous scientific and economic barriers exist, the oncology development market
has increased two-fold over the past five years.
This report aims to map current oncology R&D funding and management, primarily
in Europe and the USA, to examine public-private relationships, current oncology R&D
strategies and oncology innovation policies. Its objectives are:
• To map current funding and management of oncology R&D via questionnaire
surveys and interviews of oncology experts;
• To produce a high-resolution bibliometric analysis of oncology drug R&D in
order to better understand the public-private mix in research activity;
• To investigate the cumulative life-time funding of specific oncology drugs;
• To review current public policy affecting oncology drug R&D, specifically, public
R&D investment policies, transnational investment policies, regulatory policies,
and drug reimbursement policies; and
• To propose future oncology policies supporting the R&D process.
Results: Funding, Bibliometric Outputs and Faculty Survey
Funding
Public oncology R&D funding can be sourced from a variety of sources: national
governments, regional authorities, charities, non-governmental organisations and
supranational organisations. Funding can be directly tagged for oncology research from
these organisations or indirectly flow into oncology research via overall budgets (i.e.
hospital budgets).
Our examination of oncology funding found 153 public research funding
organisations (RFO) in the EU (UK 19, France 12, Belgium 12, Italy 11) and 21 in the
USA who spent greater than €1 million annually. The EU RFOs collectively spent €2.79
billion and the US RFOs €5.8 billion, although the EU did not include European
Commission (EC) investment which is significant and likely brings the EU figure closer
to €3 billion. Individually, the US and the UK (€1.1 billion) were the largest oncology
public R&D investors, while Germany (€426 million), France (€389 million) and Italy
xv
(€233 million) followed. Calculations per capita found leaders (USA, UK) unchanged,
however, placed Sweden, the Netherlands and Norway next. Likewise, examination of
public oncology drug R&D investment placed the USA (€1.67 billion) and UK (€305
million) at the top, regardless of absolute or per capita valuation. When direct and
indirect funding are added together, the EU invests 0.011% of GDP, or €3.64 per capita,
and the USA 0.018% GDP, or €5.74 per capita. Furthermore, the EU has significantly
increased funding by 34.7% from 2004 to 2007 while the USA increased only 9.7%.
Examination of national cancer strategies and funding found only the US and UK
with strong visions and policies, while the remaining EU countries appear to favour an
ad hoc approach. Philanthropic oncology remains impressive, estimated at over €500
million Europe and €230 million in the USA in 2007. Private oncology investment by
the top 17 pharmaceutical companies globally in 2004 amounted to €3.1 billion, 59%
from European companies. In addition, public-private partnerships (PPP) are becoming
more common, and found in 68% in the US, 57% in the EU and 31% elsewhere of new
oncology drug R&D projects.
Bibliometric analysis
Bibliometric analysis of 19 anti-cancer drug publications (1963-2009) produced
28,752 papers for analysis. Paper outputs rose from 200 annually in 1980 to 2000 by
2007-08. Examination of 15 main oncology research countries found the USA the leader
(33%) followed by Japan (10.6%), Italy (7.5%) and the UK (7.1%). Initially, the USA and
Europe dominated oncology research outputs, although recently other counties such as
China and India are increasing their publication outputs.
Neighbouring countries still favour each other (USA:Canada, UK:NL) despite
increasing international collaboration. Further, countries appear to concentrate on
certain drugs and produce less research on others. Surprisingly, most national oncology
research portfolios were poorly correlated with their internal oncology burden.
The type of oncology research performed changed with time from basic to clinical,
although per drug this was not necessarily the case. Different countries produced
different types of research (i.e. basic: India, China; clinical: Spain, Greece), with 15% of
papers describing phased clinical trials, primarily Phase II.
The presence of 26 leading pharma companies, including the 12 associated with
development of the 19 selected drugs, occurred in 1,589 papers, or 5.5% of the total.
Dominating companies responsible for oncology paper outputs were Aventis (274
papers), AstraZeneca (173) and BristolMyerSquibb (155).
Survey of oncology faculty
Faculty were surveyed on a number of public and private oncology R&D issues.
They felt strongly that PPP were important for future oncology developments, however,
its ideal definition was not clearly defined regarding financial incentives and length of
private support.
Europeans were less agreeable regarding oncology R&D
nationalisation than Americans and Canadians, while American faculty felt
reimbursement policies for new oncology drugs was less important to future successes.
All agreed, however, that the degree of national public sector investment was
inadequate to meet future oncology demands.
xvi
Faculty expressed concern about the inadequacy of current oncology R&D models,
and encouraged re-thinking of ideal models. Suggestions included greater transnational
cooperation, support of translational research and a degree of institutional involvement.
Specifically, regulatory bottlenecks must be resolved as well as ideal balance of public
versus private funding.
Policy Implications: Funding, Bibliometric Outputs and Faculty Survey
Our funding analysis produced a number of interesting issues. First, it appears there
are funding gaps between the USA and Europe, supplemented by further variations
within Europe. Second, it appears public funding is more likely to support basic rather
than applied research, while industry supports the latter. Third, European funding
appears to be fragmented concurrently with duplication and inadequacies. Fourth,
indirect and philanthropic funding appear to be significant and uncounted sources of
oncology funding. Fifth, PPP investment in oncology is of increasing importance in
addition to being complex, reducing economic risk, smoothing the operations process
and will likely play an increasing role in the future.
Our survey of oncology faculty found substantial support for PPP although its ideal
definition remained unresolved. Both public and private sources of activity and funding
are important to oncology, yet the balanced equation of their interaction and
involvement needs further study. New models specifically for oncology R&D are
urgently needed to reduce attrition rates, increase the rate and sophistication of parallel
biomarker development and work on the vast number of combination regimens and
indications necessary for the next generation of cancer drugs.
New PPP policy development should include a number of new variables:
• Strong institutional support and dedicated public RFO funding;
• Increased freedom-to-operate for translational leads within specific projects,
achieved by improved support, light-touch governance and decreased
administrative bureaucracy (national legislative, private-contractual, publiccontractual);
• Partnerships supporting trans-national co-operation and collaboration focused
on key cancers, including ‘orphans’ not viewed as commercially attractive; and
• Partnerships subject to high quality peer review and fully disclosable upon
completion to the public.
Faculty clearly identified over-regulation and reimbursement of new cancer drugs
as critical issues, which continues to overshadow public sector oncology R&D and
remains a threat to future new breakthroughs. Of further significance was intellectual
environment and infrastructure for oncology R&D, expressed as vital to institutional
and national policies. Strategic alliances and co-operation between industry and
academia are key to future oncology discoveries, as the complex nature of oncology
research cannot support monopoly in knowledge and creation. Particularly for novel
biologicals this holds true
xvii
Fostering Oncology Innovation
Encouraging innovation in oncology brings forth a number of priorities: first, the
role of science, research and innovation; second, the role of pricing and reimbursement
systems; third, the continuous evaluation of oncology drugs; fourth, the ideal
environment for long-term innovation; and, fifth, the optimization of resource allocation
in health care.
National and supra-national roles in innovation
Governments play an important role in encouraging and fostering innovation,
including direct governance for key research areas and indirect mechanisms including
taxation. Governments understand this encouragement has direct economic
consequences as well as social benefits which exceed private benefits. Collaboration
between public and private enterprises further spreads benefit and ensure greater
likelihood of success.
Despite this recognition, the complex nature of oncology requires both direct and
indirect measures.
Using only prescriptive and coercive regulations may be
cumbersome, expensive and inefficient, while output- or performance-based
regulations may have more likelihood of success. Tax incentives via R&D credits may be
targeted to serve specific objectives, while enhanced market exclusivity periods may
encourage intellectual creativity. Particularly in oncology research each player only has
a portion the knowledge required for presenting new solutions, leading to ideally open
access requirements. This presents the need for new model developments in oncology
R&D to encourage innovation leading to new treatments more quickly.
In Europe, the EC has recently taken steps to encourage innovation by promoting
translational and transnational research, in addition to PPP, in the hopes that cooperation will prove stronger than its current fragmentation. Although not all
European countries have cancer strategies in place, particularly newer members, there
is focused application to improve oncology treatments and to encourage development
of new ones. Despite this attention, there continues to be room for improvement in
European oncology R&D. Cancer charities are a significant yet neglected source of
oncology funding, their fragmentation and duplication continues to be mirrored by
many national oncology organisations. Further, some oncology research may not be
funded due to precisely its specialization and innovation, such as very specialised basic
cellular research found in only few countries, as it does not qualify for translational or
transnational funding.
In America, cancer research is less fragmented due to the umbrella organization of
the National Cancer Institute, which supports both molecular and translational research
as well as increasingly encouraging PPP. However, it does suffer from state-level and
indirect fragmentation (ie hospital research budgets), and its level of charitable
oncology R&D funding is less than the EU.
Globally, it appears translational cancer research is still in its infancy, only recent
programmes giving focus and direction. Likewise, PPP have room for growth and
direction both in Europe and the US – which should be seen as an unique opportunity at
these cross roads. Fragmentation contiues, particularly at charitable level, with some
negative consequences for administration costs and research duplication, but perhaps
benefiting highly specialised research areas still in experimental stages.
xviii
The uniqueness of rare cancers
Rare cancers represent approximately 20% of oncology cases, including childhood
cancers, each with variations in incidence, mortality and survival rates. This variability
is mirrored between EU members with regards to treatment access, information
availability and medical expertise. These factors present rare cancers as a unique case,
requiring multi-dimensional action to encourage R&D, access and uptake of new
treatments. Such actions include re-organising regulations, encouraging R&D through
collaboration, creating consensus guidelines on multi-disciplinary treatment,
addressing patient treatment access, as well as improving information access for
patients and health care professionals.
Role of the reimbursement system
Over the past decade, health care costs have increased, including drug spending
although only accountable for 10-20% of total care costs. Management of drug
spending is important, particularly as regressive management may cause access, equity
and health outcome issues. Appropriate pricing and reimbursement can help manage
health care costs while concurrently encouraging innovation in R&D and treatment. A
number of criteria can help achieve these goals.
First, timely treatment access is paramount, particularly for innovative drugs, and
encouraged through ‘fast track’ approval and reimbursement procedures (e.g. FDA fasttrack process for priority drugs). Conditional reimbursement and pricing, where access
is ensured while ‘real world’ data collection continues, as well as physician flexibility in
prescribing can further aid access and encourage innovation.
Second, reimbursement based on values, including explicit and objective
assessments is important to consider. This value should consider both societal and
individual value, and include comparisons to current best practice. Third,
reimbursement and pricing policies should contain some degree of flexibility, where
levels are adjusted as new data become available.
Fifth, collaboration should be encouraged between payers, providers and
manufacturers to explore new pragmatic ways of delivering innovative value. Sixth,
standard guidelines to assess drug benefits should include humanistic and patientfocused benefits such as quality of life (QoL), longer-term direct cost offsets, indirect
system costs, and caregiver and patient benefits.
Risk sharing
Traditionally, payers absorb all risks associated with purchasing new medical
technologies. Risk sharing attempts to redistribute the risk balance between payer and
technology supplier, typically involving the supplier to provide a ‘guarantee’ relating to
outcome. These outcomes could include clinical parameters, QoL, resource usage, , (d)
financial and economic outcomes. Although new in health care, this method is likely to
gain use in the future due to total cost issues, first, for admitting new treatments onto
national formularies and, second, to enabling faster uptake. In oncology in particular,
this could be interesting due to limited patients carrying the same genetic tumour
codes.
Continuous evaluation of oncology drugs
xix
Ex-ante evidence is currently required to present evidence for approval and
reimbusrement decisions, however, sole reliance on this method ignores evidence
outside the clinical phase environment. Ex-post evidence is just as important, however,
in proving value of new treatments yet is widely ignored. Collection and evaluation of
such data is costly, and perhaps should be shared between private and public interests,
yet is imperative in oncology with its heterogenous patients.
Optimizing resource allocation in health care
Although resources are allocated mechanistically in health care, this does not
guarantee optimal use – in fact evidence suggests that many health systems have room
for improvement including oncology. Demand-side behaviors by both clinicians and
patients, real-time information systems for payers and providers as well as system and
policy performances all must be considered. Savings emerging should be re-allocated
and re-invested to improve patient quality of care and health services.
Conclusions
The report shows oncology R&D and treatment are on the brink of a new era,
providing a unique opportunity now to redirect and refocus national, supra-national as
well as regional policies and procedures that may impact oncology directly or indirectly.
New models for PPP must be created, giving credence to both public and private
ownership within complex and often unique diseases including cancer. Reimbursement
decisions are important and can greatly impact future oncology innovation and
investment, and must be carefully considered prior to implementation (and monitored
closely thereafter). Pricing should consider innovation and value, not just with macro
societal views but also consider micro individual patients. The overall goal is improved
patient outcomes and survival, and for oncology this means collective operation and
collaboration.
xx
1. BACKGROUND AND OBJECTIVES
1. 1. The Burden of Cancer
1.1.1 Risk Factors, Incidence and Mortality
The aging of population and lifestyle factors such as obesity, physical inactivity, alcohol
consumption, rising number of female smokers and lower rates reproduction, along with
genetic susceptibility are among the most important underlying reasons for the increasing
cancer incidence in industrialized nations.1,2 However, the burden of cancer is no longer
limited to developed countries. On top of the growing risks of poor diet, tobacco, alcohol
and industrial exposures, the less developed world is already burdened with cancers related
with infectious agents3 such as Helicobacter pylori, human immunodeficiency virus (HIV),
hepatitis B (HBV), human papilloma virus (HPV) and others.2 Even if the total burden of
cancer remains highest in wealthy countries, developing countries are closing the gap
rapidly.
Advances in diagnostic methods, surgical techniques, radiotherapy, innovative vaccines
and drug treatments have contributed to improved outcomes, particularly for patients
suffering from the most ordinary cancers such as prostate, breast, colorectal and, more
recently, lung. Thus, mortality rates have stabilized in some populations (e.g. Europe).1
Still, new cancer cases were estimated at 11.47 million worldwide in 2004, while cancer
accounted for 7.42 million deaths that same year (Table 1.1, Figure 1.1).4 These figures
could reach 27 million cases by 2030 with 16 million deaths5, making cancer as cause of
death the fastest increasing rate globally, and in some countries already the primary cause
of adult mortality (UK, Netherlands).4 In most high-income countries, cancer is the second
highest common cause of death after cardiovascular disease, with lung, colorectal, breast
and stomach cancers together accounting for 13% of total mortality in 2004.4
1
Table 1.1
Global cancer related deaths and burden of disease by sex (2004)
Deaths
Thousands
Burden of disease
% total
Thousand
% total
DALYs
Both sexes
7,424
12.6
77,812
5.1
Male
4,154
13.4
41,893
5.3
Female
3,270
11.8
35,919
4.9
Source: WHO, 2008.
1.1.2 Prevalence and Direct/ Indirect Costs
Cancer prevalence refers to the burden of disease in a population and is associated with
the survival of cancer patients. In terms of total disease burden, malignant neoplasms
accounted for 14.6%, 7.2% and 2.3% of disability adjusted life years (DALYs) (‘healthy’ years
lost) in high, middle and low income countries respectively in 20044 (Table 1.1, Figure 1.1).
In the EU25 and the USA, cancer ranks third behind mental and cardiovascular disease in
relation to DALYs lost while in other industrialized countries such as Australia, Japan and
New Zealand cancer ranks second relative to DALYs lost, following mental illnesses1.
2
Figure 1.1
Cancer related deaths and burden of disease grouped by income per capita
(2004)
Source: World Health Organisation, The Global Burden of Disease: 2004 update. WHO 2008.
Despite the rising burden that cancer poses, health spending related to treatment of
cancer patients does not reflect this trend. Based on 2004 total health expenditure figures
from OECD Health Data, cancer care seems to account approximately for 6.6% (on average)
of total direct health care expenditures in most developed countries1. Medical treatments
for cancer account for 10-20% of cancer expenditure –primarily as inpatient hospital care and 5% of total pharmaceutical expenditures1.
Indirect costs associated with inability to work account for a large proportion of the total
cost that cancer imposes on society. Relevant studies demonstrate that indirect costs range
between 65-85% of total costs.6-8
1.1.3 Advancement in Cancer Medical Treatments
Various treatment methods exist today for cancer including surgery, classical
chemotherapy (i.e. agents that inhibit cancer growth such as alkylating agents and anti3
metabolics9,10), radiotherapy and an increasing number of ‘targeted’ drugs against hormone,
and growth factor receptors as well as cell-signaling pathways.
Cancer drugs are often introduced into clinical management in late-stage patients1.
Efficacy in early-stage disease often translates to greater success rates when the drug is
combined with surgery and/or radiotherapy1. Multiple drug regimens are the backbone of
treatment and the newer generation of cancer drugs promise reductions in toxicity,
improved tolerability and, in the case of orally delivered medicines, economic benefits and
increased patient satisfaction by out-of-hospital and in-community treatment delivery.
The analysis of tumour gene/protein expression profiles, as well as other technologies
such as circulating cancer cells, has driven the ‘translational’ science of prognostic and
predictive biomarkers. In the latter case such markers can help predict whether a tumor is
likely to respond to a certain treatment, the so called ‘personalised medicine’. However,
progress in genomics and proteomics has also revealed that most tumors are in practice
genetically unique and highly complex. Laboratory and clinical development of these new
biomarkers along with the next generation of cancer drugs is extraordinarily complex. As a
result, the already costly and timely research and development (R&D) process in cancer
drug development becomes even more challenging.
1.2. The R&D process
1.2.1 General Trends
Recent advances in genomics, proteomics and computational power present new ways of
understanding the inner workings of human disease at molecular level, making discovering
and developing safe and effective drugs challenging as well as promising.
Scientists in government, academic, not-for-profit research institutions and the
pharmaceutical sector contribute to basic research in order to understand the disease and
choose a target molecule. In general it takes about 10-15 years to develop one new
medicine from the time of discovery to when it is available for treating patients. Moreover,
substantial research has been carried out on estimating the costs of drug development,
4
either generally11 or according to therapeutic area12, and, although there is controversy
around the use of single numbers13 it is clear that it takes a large, lengthy effort to get one
medicine to patients. In 2005 the average cost of developing drugs against cancer was
estimated to be 20% higher (€964 million) than the mean cost of developing a new
molecular entity (NME) (€803 million)11. This number incorporates the cost of failure: For
every 5,000 - 10,000 compounds that enter the R&D pipeline, ultimately only one receives
approval.14
1.2.2 Cancer R&D
Over 50 years ago when cancer was described for the first time as a genetic disease,
hopes for early diagnosis and targeted treatments rose. However, the progress in genomic
technologies and fundamental cancer biology has unraveled a complexity among cancers
practically making each tumour’s genetic fingerprint unique.15 Therefore, it is of no surprise
that oncology R&D has the lowest success rate (and, by implication, the highest cost) of any
therapeutic area in the pharmaceutical discovery and development, making the R&D
process even more challenging for a number of reasons. Indeed, in the case of cancer, when
a molecule enters clinical trials, there's only a 5% probability that it will turn out to be a
commercially viable product.16
There are further R&D issues unique to oncology. First, instead of healthy volunteers,
patient populations who have practically failed all other treatments participate in Phase I
clinical trials. This imposes a major burden on the assessment of the safety and efficacy of
the compound, as well as the identification of relevant biomarkers. A Phase II trial, where
specific cancer types are being selected and dosage is determined, is often more
enlightening. Second, contrasting most diseases, cancer is a set of proliferative diseases
representing a variety of different specific conditions. Third, there are huge differences
among cancer patients due to the unique genetic fingerprints that almost any tumor has,
making inter-patient heterogeneity a major challenge. Finally, even if the drug makes it to
Phase III, cancer patients are normally treated with multiple drugs at the same time, thus
the standard of care has to be adapted and enhanced to add the new drug to it. Perhaps it is
5
not surprising that cancer drugs often fail in Phase III—the most costly part of drug
development programme.
The current knowledge of the biology of cancer targets and their significance in the
disease process is undoubtedly deficient and major problems remain in how to deliver many
anti-cancer agents that in vitro are effective. What seems to become increasingly likely is
that there will be a shift from defining a cancer by site17-19(i.e. malignancies originating from
the same organ system are grouped together as one single disease, receiving basically the
same treatment) to identifying similar therapeutic target cancers that, regardless of
whether they arise in the same locations or not, share alterations of the same genes. Thus,
successful cancer drug discovery will require, apart from finding the best medicine for a
certain target, also identifying the patient population whose tumors actually carry the
relevant genetic alteration, leading to both individualized diagnosis and personalized
therapy.
The issue arising here is that treating cancer as a collection of ‘orphan diseases’ could
lead to the creation of smaller markets, inapt to the traditional ‘best-seller’ model of
discovering and developing new cancer drugs.20 Indeed, some pharmaceutical companies
have been reluctant to invest in early basic science and preclinical research and
development, given the limited revenue prospects of such a business model.
In the end, it seems that the overabundance of these potential targets are major
scientific hurdles to issues of drug delivery, target appraisal and confirmations and potential
medicines manufacturing and effectiveness enhancement. Furthermore, the development
of new therapeutic strategies is too much for industry, government or universities to do
separately. Collaboration appears to be the key to facilitate the discovery and development
of effective new cancer drugs and optimize their application.
6
1.3. Trends in R&D spending and output by the private sector
1.3.1 Aggregate R&D trends in pharmaceutical and biotechnology industries
While total pharmaceutical R&D expenditurea has increased and salesb have grown,
revenue keeps on relying on a small number of molecules reflecting an ongoing drop in
productivity (Figure 1.2).
R&D costs continue to rise with development, now corresponding to approximately one
third of all spending. Development times also continue to grow during all phases of
development. Discovery and regulatory times have not marked any significant change
during the past 5 years and are not expected to do so in the years to come.21 Still, there is an
obvious trend in some companies to invest more in early development in order to avoid the
massive cost of late-phase failure.
a
This includes expenditure on R&D funded by grants or in-licensed to other companies or institutions, and
proportional expenses for joint ventures. R&D refers to personnel-related costs such as salaries, consumables, and a
suitable share of expenditure to account for administration, depreciation, rent, etc. but capital R&D expenditure is
excluded.
b
This includes complete products and bulk sales as well as royalties from licensed out medicinal products.
7
Figure 1.2
Global R&D expenditure, development times, NME output and global
pharmaceutical sales (1997-2007)
Notes: Each trend line has been indexed to 1997 values
Development time data point for 2007 includes data from 2006 and 2007 only
Source: CMR International & IMS Health
On the other hand, success rates are not improving as only 20% of molecules entering
Phase II will be marketed. Biotechnology-derived and self-originated substances do have,
however, a slightly better chance of success relative to chemical and in-licensed entities.19
Consequently, the number of NME launches dipped to a new twenty year low in 2007,
despite the encouraging signs in 2005. In fact, during the 1997-2007 period the introduction
of NME dropped by 50%. Yet, biotechnology products have accounted for almost a quarter
of all NME launches.19
The molecules currently in development are mainly looking at therapeutic areas with
high value and significant level of unmet medical need.13, 20 The underlying rationale is that
although molecules with a new action mode are associated with a significant success risk, at
the same time they offer the greatest opportunity for innovative and high-value medicinal
products. 22
8
1.3.2 Cancer R&D Trends
As previously been described, R&D in the area of oncology is particularly challenging.
However, oncology-related R&D is booming and this is shown by the enormous share of
oncology compounds in the pharmaceutical sector’s clinical pipeline. In the USA alone there
are more than 800 new compounds in development for cancer in 2009, compared with 750
in 2008 and just under 400 in 2005c (Figure 1.3).
Figure 1.3
Number* of new cancer drugs in development by type of cancer
Note: Some drugs are listed in more than one category
Source: PhRMA (“New medicines in development for cancer”, 2005; 2008; 2009).
This reality reflects the focus of R&D investments towards therapeutic areas and
technologies of greatest opportunity (perceived as a combination of low generic penetration
c
PhRMA reports on new medicines in development for cancer.
9
and high price levels), associated with the highest unmet medical need. Hence, the
opportunity associated with a potential success cancels out the fact that attrition rates
among cancer products are as high as 95%.
1.4. Aim of this report
The global organisation and funding of cancer research follows many different models. The
global flow of knowledge, innovation, research and development has dramatically increased
the complexity of cancer research. Since the mid-1950s cancer drug development has
become the dominant area of cancer research. The clinical need to find drugs to prevent
cancer, suppress recurrences (adjuvant), downstage tumours for surgery (neo-adjuvant),
treat metastatic disease and palliate has driven the development of new molecular entities,
be they chemical or biological.
However, the vast complexity of this nexus coupled to the widely different paradigms
that appear to operate across Europe, USA and the Far East do not easily lend themselves to
strategic analysis. In particular questions arise as to:
•
What models of funding and management have, or have not been successful;
•
What is the most efficient, creative and innovative model for public-industry
cooperation and collaboration; and
•
What policies should we be developing to support drug development in cancer,
and to whom should these be directed (government, NGOs, etc).
In this context, the aim of this report is to map out the current funding and management
structures for cancer drug R&D in Europe and the USA, with particular reference to the
public-private interplay, and following a review of current strategies put forward
recommendations to improve cancer drug innovation.
The report focuses on the USA, Germany, UK, Italy, France, Netherlands, Sweden and
Spain primarily, but also includes evidence from EU27 and Canada, where it is available.
Although the main focus is on adults, the report includes paediatric oncology as drug
development in this area is now a critical public policy issue.
The detailed objectives of the research presented in the report are fivefold:
10
First, to map current funding, peer review and management of cancer drug
development. Through a mixture of questionnaire- and interview-based techniques, the
current funding in oncology, peer review and management practices is mapped for the
countries in question. This encompasses pre-clinical drug development, early phase clinical
trials through to pivotal phase III, although in the latter case this is assumed to be entirely
within industry. The report covers both New Chemical Entities and Biologicals. This
addresses the question as to who funds what and how. Within the institutional part of this
mapping exercise the report drills down into the availability (or otherwise) of key platform
technologies and infrastructure for the pre-clinical and clinical aspects.
Second, the report conducts and presents a high-resolution bibliometric analysis of
outputs in drug development with a view to obtaining a better understanding of the public
private mix in cancer research activity. Apart from early phase clinical trials where we know
publications (outputs) do not reflect activity, the research presented in this report uses
bibliometrics as a means of understanding current and past state of cancer drug
development. The research uses major databases and constructs with key drug names to
analyse the trends in output and impact by country, institution and even researcher. It
examines how models of partnership (institution-to-institution and institution-industry)
have changed and also at the patterns of funders over time. Such changes can then be
reviewed in the context of the impact of national policies.
Third, to investigate the cumulative life-time funding of specific cancer drugs. The
question of how and who funds cancer drug development can most effectively be answered
by looking at the cumulative lifetime from inception/discovery (NME) to clinic. Taking a
representative sample of current cancer drugs the report looks at their funding histories
from inception to market.
Fourth, to review the current public policy affecting cancer drug development. There is
substantial literature on the generic process of drug development (essentially data
documents) and specific policy issues (e.g. Intellectual Property) but few which are either
disease-specific or take a horizontal approach to the affect of policies (i.e. how different
policies interact with each other in a cumulative manner). This report reviews five streams
of current public policy which affect cancer drug development both in Europe and the USA,
notably (a) policies affecting public R&D investment in cancer research, particularly at
11
Member State & Institutional (University-Hospital complex) level and differing polices
around public-private ventures; (b) transnational investment polices focusing on funding by
bodies such as the EU Commission compared to the US NCI; (c) regulatory policies,
specifically the clinical trials directive; (d) tax and IPR policies; and (e) the likely impact of
drug reimbursement policies on the development of cancer drugs.
Finally, to propose polices to support further cancer drug R&D. This objective has been
informed by the emerging evidence in this report as well as by key opinion leaders (senior
clinicians) in cancer drug discovery and development with a view to proposing key public
policy measures to support innovation in European cancer drug development.
Section 2 places cancer research in context by providing a historical background to
cancer drug development; Section 3 presents the public and private trends in cancer drug
research and development; Section 4 presents the results of the investigation into the
cancer research activity in both the public and private sectors, whereas Section 5 builds on
the senior clinician survey to propose policies to support cancer drug R&D. Section 6
debates the issues surrounding public policies affecting cancer drug development. Finally,
Section 7 draws the main conclusions and considers the policy implications.
12
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drug development costs. J Health Econ 22(2):151–185.
12. DiMasi JA et al (1995). R&D costs for new drugs by therapeutic category: a study of the
US pharmaceutical industry. PharmacoEconomics 7(2):152-69.
13. Adams CP, Brantner VV (2006) Estimating the cost of new drug development: is it really
802 million dollars? Health Aff (Millwood) 25(2):420–428.
14. PhRMA, 2007. Drug Discovery and Development: Understanding the R&D process
Pharmaceutical Research and Manufacturers of America, 2007.
15. Lengauer C, Diaz LA, Saha S (2005) Cancer drug discovery through collaboration. Nature
Reviews, Drug Discovery 4:375-380.
16. Clinton P (2007) R&D Innovation: An Answer to Cancer (interview of Joseph Bolen,
Millennium CSO and chairman of the 12th Annual World Congress on Drug Discovery
and Development of Innovative Therapeutics in 2007).
http://pharmexec.findpharma.com/pharmexec/PE+Features/RampD-Innovation-AnAnswer-to-Cancer/ArticleStandard/Article/detail/463103
13
17. Bardelli A. et al (2003) Mutational analysis of the tyrosine kinome in collateral cancers.
Science 300: 949.
18. Lynch TJ et al, (2004) Activating mutations in the epidermal growth factor receptor
underlying responsiveness of non-small-cell lung cancer to gefitinib. NEJM 350:21292132.
19. Paez JG, et al (2004) EGFR mutations in lung cancer: correlation with clinical response to
gefitinib therapy. Science 300:1497-1500.
20. Booth B, Glassman R, Ma P (2003) Oncology’s trials. Nature Reviews, Drug Discovery
2:609-610.
21. CMR International 2009 R&D compendium, Epsom, UK.
22. Russell M, Gjaja M, Lawyer P (2008) The future of Pharma: adjusting the Pharma R&D
Model, Boston Consulting Group, April 2008 in the PAREXEL’s Bio/Pharmaceutical R&D
Statistical Sourcebook 2008/2009; 27-28.
14
2. THE HISTORY AND SCIENCE OF CANCER DRUG
DEVELOPMENT
This section provides a brief journey through the major historical developments in
European cancer research and a discussion of the key areas of current cancer drug discovery
– new chemical entities and biologicals (immunotherapy).
2.1. A European History of Cancer Research
Europe’s seminal contributions to the milestones of cancer research are many and can
be traced back to 1889 when Dr. Stephen Paget, a London surgeon, developed the “seed
and soil” hypothesis of metastasis.
The prevailing view at that time was that cancer cells spread through the blood or lymph
and could take up residence in any tissue. If this had been true, metastases would have
shown a random distribution to other organs. Paget thought otherwise. “When a plant goes
to seed, its seeds are carried in all directions. But they can only live and grow if they fall on
congenial soil…” he wrote (one of the wonderful things about research in this era was the
use of the natural world as an unlimited source of metaphor and analogy, sadly lost in
today’s prosaic research culture). Paget examined nearly a thousand cases and found that
specific tumours metastasized consistently to particular organs.
Although this view was challenged by James Ewing, who gave his name to a type of soft
tissue cancer, or sarcoma, claiming instead that metastases settled in the first organ they
reached as they spread through the vasculature, Paget was to be proved correct in 1980 by
Isaiah Fidler and Ian Hart working at the MD Anderson Cancer Center at the University of
Texas.
Almost simultaneously with Paget in 1890, just a few years after the discovery of
chromosomes, David P. Hansemann, a pathologist-in-training with Rudolph Virchow in
Berlin, produced a theory of the pathogenesis of cancer. This included a key concept: that
the first change which occurs in cancer is an alteration of the hereditary material of a
15
normal cell at the site where the cancerous process begins. In the process of linking cancer
to
chromosomal
material,
Hansemann
coined
the
terms
“anaplasia”d
and
“dedifferentiation”.e These terms have remained the basis of descriptive terms concerning
the microscopic appearances of tumours ever since.
The great German tradition in cancer research continued with people such as Theodor
Heinrich Boveri (1862 –1915), a German zoologist. In his work with sea urchins, Boveri
showed that it was necessary to have all chromosomes present in order for proper
embryonic development to take place. His other discovery was the centrosome (1888)
which he described as the special organ of cell division. He also reasoned that cancer begins
with a single cell, in which the make-up of the chromosomes is scrambled, causing the cells
to divide uncontrollably.
It was Paul Ehrlich who was to make the link between the immune system and cancer,
suggesting that for the latter to survive the former had to be suppressed. Paul Ehrlich, who
won the 1908 Nobel Prize in physiology and medicine, also predicted autoimmunity calling it
“horror autotoxicus”. He coined the term “chemotherapy” and popularized the concept of a
“magic bullet”.
However, one should not view Europe’s role in turning back the tide of cancer as an
isolated one. Then, as now, research was a complex dance over distance and time. Europe’s
great contributions are intimately intermingled with those in other countries and
continents.
Europe has also laid the foundations of many other domains of cancer research. The
most important discovery in the history of cancer epidemiology was the carcinogenic effect
of tobacco. The pivotal studies begun by Sir Austin Bradford Hill and Sir Richard Doll, and
later with Sir Richard Peto, were to provide the springboard for five decades of research on
both sides of the Atlantic.
d
e
Reversion of cells to an immature or a less differentiated form, as occurs in most malignant tumors.
Regression of a specialized cell or tissue to a simpler, more embryonic, unspecialized form.
Dedifferentiation may occur before the regeneration of appendages in plants and certain animals and in the
development of some cancers.
16
In surgery there have been many seminal contributions by the European cancer research
community. Umberto Veronesi, an Italian surgeon and oncologist, was the founder of
breast-conserving surgery, inventing the technique of quadrantectomy, which challenged
the idea, then dominant among surgeons, that cancers could be treated only with
aggressive surgery.
Europe has been at the forefront of treating bowel cancer through surgical advances –
from 1908 when Ernst Miles first described the abdominoperineal resection, to the first
description of total mesorectal excision by Bill Heald and colleagues in 1982. This gave rise
to clinical trials in Scandinavian countries that were to change global clinical practice.
The recent breakthrough in controlling cervical cancer through the use of a vaccine
directed against certain types of human papilloma virus (HPV) rests on the work of Harald
zur Hausen, who was first to show that the papilloma virus was the most significant cause of
this cancer. In turn, that work owed much to the groundbreaking research begun in 1910 by
Peyton Rous who first discovered tumour viruses.
Research into the molecular and cellular biology of cancer has provided remarkable
insights into the molecular basis of cancer, such as disordered cell proliferation, disturbed
differentiation and altered cell survival, and disruption of normal tissue, invasion and
metastasis. New discoveries in the molecular oncology of tumours in the last few decades
have led to major improvements in cancer therapy. In the middle of the twentieth century
an improved molecular classification of malignant lymphomas paved the way for
individualized therapy in cancer. The treatment based on these molecular classifications
resulted in higher response rates and improved survival of patients with malignant
lymphomas. One of the most prominent scientists involved in this molecular pathology
research and one of the authors of the new Kiel classification of lymphomas was Karl
Lennert, a German pathologist.
The field of breast cancer, the most frequent cancer in women, has seen many new
developments based on the European research shared with other countries. Pivotal
experiments performed in the late 1950s and early 1960s, primarily in the laboratories of
Gerald Mueller and Elwood Jensen in Germany and the USA, set the stage for the
development of hormonal therapy in hormone-responsive breast cancer. Acknowledgement
of hormone receptors as one of the major biological determinants of breast cancer was
17
actually one of the first discoveries that enabled the most effective strategies in the
treatment of cancer, i.e. targeted therapy. Hormonal therapy with tamoxifen was the first
individualized, targeted therapy in the history of cancer therapy.
Nowadays, breast cancer can be divided into hormone-receptor-positive and hormonereceptor-negative tumours, with treatment being substantially different in these two
distinct diseases. Based on the largest meta-analysis in cancer care, undertaken at Oxford by
Sir Richard Peto and his co-workers in the Early Breast Cancer Trialists’ Collaborative Group,
a vast amount of knowledge on the best possible adjuvant systemic therapy in hormonepositive and hormone-negative breast cancer was accumulated. Their work confirmed that
adjuvant chemotherapy reduced the rate of recurrence by 33% and the rate of breast
cancer death by 17%, saving thousands of lives of women with breast cancer. The same was
true for hormonal therapy in hormone-responsive breast cancer, in which adjuvant
hormonal therapy with tamoxifen was found to reduce the rate of recurrence by 41% and
the rate of breast cancer death by 34%, according to the data from the meta-analysis.
Adjuvant systemic therapy, in addition to surgery, radiotherapy and screening programmes
has been responsible for major declines in breast cancer mortality during the last two
decades in the USA and Europe.
In 1971 when Richard Nixon proclaimed war on cancer “a quick and decisive victory was
predicted”.f However, despite the expenditure of billions of pounds and some real
improvements in survival, especially in paediatric oncology, the morbidity and mortality
associated with cancer remains high. Although the majority of cancer treatments are due to
the surgical scalpel and radiotherapy it is advances in chemotherapy that hold the key to
controlling and ultimately defeating cancer.1
f
The war on cancer. In: www.usnews.com/usnews/issue/cancer.htm.
18
2.2. New Paradigms in Chemotherapy
The problem with conventional cytotoxic chemotherapy is rather obvious – the
therapeutic window is narrow and only partially effective. This leads to poor efficacy and
tolerability, as well as the development of serious adverse reactions. Combination
chemotherapy has been the intellectual development to address the former issue but at the
expense of tolerability and toxicity. Chemotherapy that targets all abnormal cells whilst
sparing normal tissues has seemed a distant prospect, but now the ability to probe the most
intimate details of the cell through the application of genomic and proteomic technologies
has the potential to fulfil this dream. At the heart of this is the vision that new
chemotherapy can be developed to selectively target cancer.2 The new paradigm couples
technology, such as robotic high-throughput screening, combinatorial chemistry, structural
biology and molecular modelling with new insights into the pathophysiology of cancer and
therefore new therapeutic strategies, e.g. the role of new blood vessel formation for
metastatic disease and development of anti-vascular and angiogenic agents.3 There have
been encouraging signs that this approach may work. A signal transduction inhibitor
(Imatinib) that selectively targets the abnormal BCR-abl fusion protein (Philadelphia
chromosome product) that drives Chronic Myeloid Leukaemia, has demonstrated
remarkable efficacy, with little toxicity. The more that we learn about cancer biology the
more approaches present themselves – growth factor receptors, immune system
modulation, cellular matrix, targeting of proliferation, migration and survival (apoptosis).
Natural product drugs that continue to play the dominant role in armoury of therapeutic
options are also complimenting designer chemotherapy. Some of today’s most clinically
successful chemotherapies are derived from nature – paclitaxel, vincristine, vinorelbine and
analogs of camptothecin.4 In fact in the last fifty year,s only the rational structural design of
5-fluorouracil by Heidelberger has bucked the serendipity trend.5 However, since the early
1990s this has changed dramatically with agents designed against rational targets –
cetuximab, bevacizumab, to name but two. The hope is that efficacy can be enhanced by
combining these cytotoxics with the newer targeted agents. Furthermore, it has become
apparent that individual responses – efficacy and toxicity – are in part determined by
genetically determined factors. This has led
19
to
the
emerging disciplines of
pharmacogenomics and pharmacogenetics that, using emerging technologies such as single
nucleotide polymorphism typing, aim to tailor chemotherapy.6 However, this is still a very
nascent field that has yet to be fully validated.
The past ten years has seen a paradigm shift in cancer drug development away from
direct acting anti-cancer agents, be they antibodies, novel signal transduction inhibitors or
conventional cytotoxics which have been at the heart of chemotherapeutic strategies for
more than forty years. Conventional wisdom underpinned by solid evidence from
randomised controlled trials dictates that direct tumour cytotoxicity is an effective strategy.
However, in spite of success in curing a variety of cancers from paediatric to adult with
modest gains in the adjuvant/neoadjuvant setting for a sub-set of patients as well as much
needed palliation in other settings, the fact remains that new strategies, or combinations of
strategies, are needed to deal with advanced, metastatic disease.
2.3. Attacking Cancer
Cancer cells, despite their escape from normal intra and extra-cellular controls, are still
highly dependent on interactions between their cell surface receptors and other cells (cellto-cell adhesion), growth factors, cytokines, hormones and elements of the extracellular
matrix. Furthermore they must continue to evade immune detection and, beyond a certain
size, need to stimulate new blood vessel growth – angiogenesis. Targeting the world around
the cancer cell is role of indirect acting anticancer agents.
Remarkably, targeting the tumour blood vessels as a therapeutic option was first
suggested some 20 years ago by Juliana Denekamp and colleagues at the Gray Laboratory
writing in the British Journal of Cancer. Aided by quantum leaps in technological
development, particularly in real time imaging of vascular flow and function through such
techniques as dynamic contrast-enhanced – magnetic resonance imaging (DCE-MRI),
positron emission tomography (PET) and laser doppler flowmetry, targeting angiogenesis
was been a leading research area. Two broad fronts have been engaged. One approach
targets the intracellular protein tubulin and has the dual attraction of acting as a mitotic
poison for tumour cells and an antivascular agent. Various novel candidates are in
20
development and early phase clinical development has been completed for combretastatin
A4 phosphate.7
The other front has been to exploit the differential expression of endothelial surface
proteins. Various approaches are being trailed including immunotoxins, and targeted gene
therapy. Multiple mode-of-action agentsg are also being examined. One of the most
promising agents to demonstrate exceptional antivascular properties is a low molecular
weight compound termed DMXAA, derived from the non-steriodal anti-inflammatory
flavone acetic acid.8 This is currently the focus of a number of studies. More advanced and
well validated approaches have been through the targeting of blood vessel growth factor
receptors utilising recombinant humanised monoclonal antibodies or small molecule
inhibitors.h
The dual finding that many solid cancers not only have deregulated signalling pathways
but also trigger new blood vessel formation by the cancers suggests a need for combination
direct / indirect strategy. One such new molecular entity that takes this approach is a
pyrrolo-pyrimidine derivative (AEE788), and dual inhibitor of both these pathways which has
reported activity in pre-clinical models, particularly head and neck squamous cell carcinoma,
a tumour notoriously resistant to treatment.i Although exciting science, it remains to be
seen whether these ‘2-in-1’ agents are better than combining two different classes of agents
e.g. antibody against VEGF and tyrosine kinase inhibitor for EGFR, or vice-versa.
Interestingly, it is not just novel compounds with dual mechanisms-of-action (indirect &
direct acting) that are attracting interest. Thalidomide appears to exert its anti-cancer
activity through numerous actions via growth factors tumour blood vessels and cytokine
modulation.
Broadly speaking, immuno-modulationj has not proved itself yet to be the success that
William Coley’s seminal work in the 19th century suggested it could be. Coley, a New York
g
such as arsenic trioxide.
h
such as Sugen’s SU5416 and SU6668.
i
AACR-NCI-EORTC Molecular Targets and Cancer Therapeutics Nov 17-23 2003. Abstract Numbers: A87 &
102.
j
Defined as the adjustment of the immune response to a desired level, as in immunopotentiation,
immunosuppression, or induction of immunological tolerance.
21
surgeon demonstrated clinical remission in advanced cancer patients treated with an
mixture of inactivated S. pyogens and Serratia marcesens, work that was not reported until
after his death by the careful scholarship of his daughter Helen Nauts.9 Modulation of innate
and adaptive immunity has been a complex and difficult task. One approach has been to
target cytokinesk. A number of these molecules with a variety of immuno-modulating
properties are currently being assessed in clinical trials with some (e.g. IL-2, IFN-α/γ, TNF-α)
at late stage development.10 Many cytokines have also been shown to be important survival
factors for various tumours, for example IL-6 for breast and prostate cancers. IL-6 has also
been shown to enhance pancreatic cancer survival, cell migration and proliferation in the
presence of HER2 inhibition. Such insights are vital for guiding potential combination
therapies, in this case for instance this work suggests that without IL-6 inhibition any HER2
targeted therapy, e.g. trastuzumab (Herceptin) would be at the very best ineffective. A dual
indirect/direct acting strategy is also being employed by the generation of antibodies fused
to cytokines.11 Recombinant cytokines are also being combined with other indirect acting
immunological therapies including cancer vaccines.12
Numerous approaches have been utilised in developing cancer vaccines from tumour
antigens to naked DNA or RNA.13 Despite early disappointment that vaccines failed to
demonstrate clinical efficacy, promising immuno-stimulation has been achieved and new
approaches such as DNA vaccines, particularly if used in combination therapies, have the
most realistic prospect of success. Likewise, promising early results with dendritic cell
vaccines (DC’s are essential for the induction of adaptive immunity) have not been
replicated in larger trials. Part of the problem may lie in DCs’ interactions with growth
factors.14 Either such inhibitory networks need to be circumvented or inhibited by targeting
the relevant growth factor.
k
Are a category of signaling molecules that are used extensively in cellular communication. They are
proteins, peptides, or glycoproteins.
22
Anti-cancer agents targeting the tumour environment are essential for a number of
reasons, namely the ability of cell-cell and of cell-matrix interactions to:
•
Enable immune evasion
•
Act as proliferation and survival signals
•
enhance migration (metastasis)
•
enable tumours to acquire multi-drug resistance (MDR)
Part of the problem with targeting the tumour environment has been the difficulty in
identifying key, rate-limiting factors, and therefore potential targets that support cancer cell
proliferation and survival. Even when such factors are identified, there remains the difficulty
of tumour selectivity in any therapy designed against a component of the normal
extracellular matrix – the tissue architecture in which normal cells function. However, there
are encouraging signs of progress in identifying novel targets in the extracellular matrix that
surrounds cancer cells and in further determination of their pathophysiological role.
Spangaletti and colleagues have recently demonstrated the importance of a basement
membrane organising protein, Sparc, secreted from stromal cells, for the immune
protection and development of new blood vessel formation for breast cancer cells.15
The observation that the extracellular matrix surrounding tumour cells can protect
against inhibition with new chemical entities targeting signaling pathways suggests, again, a
need for dual direct / indirect anticancer therapies. The multifactorial nature of drug
resistance will also require combination therapies that can target a variety of environmental
factors from extracellular matrix proteins to key growth factors and cytokines.16
Development of novel screening methodologies, such as Target Related Affinity Profiling
(TRAP), have also led to further developments towards first-in-man trials, in this case the
identification of novel small molecule lead compounds against targets implicated in
promoting tumour proliferation and survivall. Another major area of research has been in
preventing cancer cell migration / invasion through the use of matrix metalloproteinase
inhibitors such as marimastat, and the Bayer and Bristol-Mayers-Squibb compounds BAY129566 and BMS275291. The universally negative results to these compounds to date indicate
l
AACR-NCI-EORTC Molecular Targets and Cancer Therapeutics Nov 17-23 2003. Abstract No A18
23
a deficiency in our knowledge about the actual patho-physiological of migration / invasion.
More research is needed to understand the complex interplay between tissue architecture,
secreted growth factors, non-cancerous and cancerous cells if rationale combination
strategies are to be formulated.
Will these strategies be a solution? By themselves it is unlikely, but in combination (e.g.
targeting various in-direct domains - angiogenesis, growth factors etc, or with direct acting
agents) there is real potential. Substantial difficulties remain – resistance secondary to
plasticity in the various signaling pathways, the potential for significant side-effects,
insufficiently ‘potent’ anticancer activity and the difficulty of designing agents with sufficient
selectivity, as well as the perennial problem of delivery.
In his concluding remarks to the 12th Annual Pezcoller Symposium, Ed Harlow
commented that it would be important to utilise complex read outs to spread information
on how different actions interact in a cell as well as the combined expertise of different
laboratories; this was just to address single cancer cell signaling pathways.17 In fact,
integrating anti-cancer strategies is an order of magnitude greater in complexity for
dissecting biological cross-talk and key interactions compared to the level of single cancer
cell and its signaling pathways. There remains much to understand mechanistically about
tumour-environment interactions, but the goal must be to try out these combinations in
imaginative and perhaps even in empirical manners. There is now good evidence that
tumour responses are a group phenomenon rather than the summed responses of
individual cells to injury. Thus the classic description of the bystander effect in radiation
oncology may be relevant to chemotherapeutic strategies where indirect and direct acting
anti-cancer agents are combined to substantially enlarge the direct injury to the tumour
cells.
How is this likely to be best achieved? Clearly the parallel investigation of cancer biology
and selection of new indirect/direct-acting combination strategies requires integrated
clinical studies that maximise pharmacological, cellular biological and molecular pathological
information capture. The ability to take time and explore unusual or counter-intuitive
avenues will be essential. Strong academic centres supported by high quality organisational
structures funding specific projects underpinned by long term programmatic funding are the
ideal environment to investigate these complex areas.18 This strength has already led to
24
substantial biotech spin-offs and provides a rich environment within which public-private
partnerships can work to tackle these therapeutic challenges.
2.4. Biologicals for Cancer Therapy
The last decade has seen a surge of research and development focused on biologicals,
which must be considered now as being one of the hottest areas for anti-cancer drug
discovery.
Last year was the celebration of the 100th anniversary of the ‘birth’ of immunology
following the Nobel prize award to Paul Ehrlich and Elie Metchnikoff. Ehrlich was the first to
demonstrate humoral adaptive immunity (the antibody arm of the immune system) while
Metchnikoff’s discoveries of the critical host-defence of phagocytosis, notably the
engulfment of cellular debris and pathogens, made him the father of cellular innate
immunity. As in all matters of science, progress since these heady days has not been
smooth. A chemical explanation for Ehrlich’s discoveries was sought, but quickly came to a
dead-end. It took Frank Burnett’s and David Talmage’s theory of clonal selection to bring
matters back on track but it would not be until 1939 that Susumu Tonegawa would solve
antibody diversity using the then newly acquired tools of molecular biology, and so set in
motion developments which were to lead to today’s great array of therapeutic antibodies.
On the other hand it took nearly a 100 years to fully understand what Metchnikoff started;
that non-specific cellular and specific humoural system are complimentary and of equal
importance.19
Immunotherapy to treat cancer also had the good fortune to find one William Coley,
then at the hospital destined to become the Memorial Sloan-Kettering, who first used
bacterial toxins to induce responses in sarcoma.20 Whilst extraordinary progress has been
made in the development of cancer biologics as well as their application in other
diseases(e.g. in monoclonal antibodies – both therapeutic and diagnostic; therapeutic
interferon’s and interleukins and human growth factors for supportive care),
disappointments and set-backs still fog this therapeutic domain. Despite, or perhaps
because of these issues, immunotherapy generates huge excitement.
25
The recent TGN1412 (anti-CD28 monoclonal) clinical trial for certain types of blood
cancers gave an unwelcome insight into how much and yet how little we really understand
about the human immune system. With so much work carried out on animal models it is
now becoming clear that the only realistic model is man. As Adrian Hayday and colleagues
point out we do not even have a good physiological definition of a healthy human immune
system.21 From an evolutionary standpoint it is perhaps no surprise that as a species we
seem to be so very immunologically different. The hominin lineage (the evolutionary line
from which Homo Sapiens descended) has penetrated every ecological land niche on this
planet and immunological plasticity has been mandatory. Indeed, from the 30 or so extant
animal phyla examined by comparative immunology, it is now clear that there has been a
huge acquisition of immuno-complexity leading to totally unforeseeable alternatives in
immune receptor diversification and systems interaction. In light of this knowledge,
developing complex immuno-therapeutics is inevitably an exercise in stochastic
experimentation rather than rationale development.
In an excellent article Antony Melcher, Peter Selby and colleagues set out the state-ofknowledge in how the human immune system does (or not) respond to cancer.22 Whilst
studies
of
Tumour-Infiltrating
Lymphocytes
(TILs)
provide
a
strong
case
for
immunosurveillance of established cancer, precious little is known about the ability of the
immune system to detect and clear pre-clinical tumours. Animal model(s) have suggested a
role for NK, NK T cells, alpha/beta T cells as well as gamma/delta T cells. New concepts such as immuno-editing composed of three phases of elimination, equilibrium, escape – if
supported by further in vivo studies would greatly aid many avenues of immunotherapy
development.
In the same vein, work over the last five years has placed the relationship between the
emerging tumour and stromal tissue centre stage. This complex and dynamic process injects
a new paradigm into the overall theory of immuno-editing by seeing immune-cancer
interactions across the spectrum from quiescence to low level inflammation and to full
blown acute reactions. Specific studies on how tumour cells interact and exploit
complement open up new theoretical avenues for therapy.
Part of the translation problem lies in the fact that some of the ‘basic’ knowledge about
the human immune system is lacking. The question that has exercised researchers is how to
26
address this. While ‘big science’ is always controversial, the jury appears to be coalescing
around the idea that a human immunological genome project is needed to establish
essential genetic road maps.23 The obvious problem is that this would still be a long way off
from understanding the 4-D immuno-oncology system (the interaction between the
immune system and the initiation and development of cancer), but in order for the systems
biologists to really understand such a problem perhaps the time has arrived to launch such
an initiative. Such a project, properly integrated with some of the key global programmes in
cancer immunotherapy R&D, might well fill in key lacunae in our basic understanding.
Broadly, the efforts to treat cancer with immunotherapy have included the use of
cytokines (e.g. IL-2 to treat malignant melanoma), adjuvantsm (e.g. BCG to reduce
recurrence of bladder cancer), the far less successful attempts utilising vaccines and other
approaches. The crowning achievement, has been the use of humanized monoclonal
antibodies (MAb) which continue to be developed into new therapeutic niches, e.g. by the
harnessing idiotypic networks to elicit tumour-antigen specific immune responses.
Moreover, MAb make commercial sense with studies showing a higher success rate than
small molecules (14% compared to 10% between 1990-2007). In an attempt to leverage the
success of trastuzumab and bevacizumab pharma continues to re-stock its immunotherapy
pipeline with biotech specialising in humanized antibodies (MAb). Unfortunately, however,
many cancers develop resistance to MAb, or are refractory from the outset, which has
spurred a raft of work into immunotoxins. These immunoconjugates, notably processes
where an antibody is bound to a novel ‘warhead’, are now being developed to use a wide
range of ‘warheads’ including chemotherapeutic agents, radioisotopes, enzymes or toxins.24
Some immunotoxins, e.g. IL-13 and EGFR targeted agents, are now in phase III clinical trials
(both against glioblastomasn) but the majority remain at an early stage of development.
One of the major issues is, whereas haematological malignancies appear to be
responsive, solid tumours are not, probably due to a combination of immune system
m
Adjuvants are pharmacological or immunological agents that modify the effect of other agents (e.g.,
drugs, vaccines) while having few if any direct effects when given by themselves.
n
Glioblastoma multiforme (GBM) is the most common and most aggressive type of primary brain tumor in
humans.
27
impairment secondary to previous therapy and the lack of accessibility of the immunotoxin.
One fascinating approach to tackle solid tumours is by targeting cancer stem cells (CSC) with
MAb. This exciting area suggests that the major cause of conventional treatment failure is
an inability to kill off the CSC, which then give rise to a highly aggressive and resistant
population.25 Three approaches are now in pre-clinical development – OMP-21M8 against
multiple solid tumours, RAV17/RAV18 against prostate and colon and ARH460-16-2 against
leukaemia, breast, colon and prostate. All these biologicals utilise novel and complex
mechanisms of action to target cancer stem cells.
Beyond the enhancement of MAb immunotherapy using toxin conjugates, one of the
key areas for development is their combination with chemoradiotherapy. In the case of
radiotherapy the evidence that it can promote sufficient ‘danger’ signals to enhance
immunotherapy, particularly lymphocyte trafficking, is thin. However, there is 20 year old
data which suggest that such an effect may be possible.26 The need now is to follow this up
with specific studies. The ability of chemotherapy to augment immunotherapy is highly
attractive. There are numerous ways in which this could, from a mechanistic standpoint, be
achieved but the myelosuppressive (reduction in bone marrow activity) nature of many
regimens coupled with many tumour kill mechanisms often generating either weak danger
signals for immunotherapy and / or tolerating effects is a serious challenge. Two notable
recent failures, both in lung cancer, provide salutary lessons. The first was the failure of a
MAb bevacizumab & EGFR inhibitor erlotinib combination to arrest non-small cell lung
cancer (NSCLC), and second, the poor showing of a heat killed suspension of Mycobacterium
vaccae (SRL172) again in a phase III against NSCLC. There were tantalising indications of
activity in both cases, particularly an enhancement of response rate and median progression
free survival in the first combination. However, the effect may well have been diluted out by
NSLC heterogeneity as well as an enhancement of survival from additional therapies after
each progression.
Two clear lessons come out of these experiences. The first is the need to be much more
selective about patient selection criteria and tumour type, although this does then beg the
question as to the commercial viability if indications become increasingly narrow, and the
second is the need to rebuild and maintain the immune system if immunotherapy is to be
an effective add-on to conventional chemotherapy.27 Furthermore, defining immunogenic
28
regimens and schedules will be key to taking this approach forward; for example
temozolomide is known to be a powerful inhibitor of the immune system and gemcitabine
depletes B-cells and so would be a poor choice for combination therapy with a biological.
There are four important issues to consider in designing an effective cancer vaccine: how
to prevent immune evasion, how to avoid autoimmune pathology, how to stimulate an
effective anti-tumour response, and finally, how to identify potent tumour rejection
antigens.28 Sadly, few have made it through to the clinic and when one takes the most
cursory look at the range of approaches it is clear that this field is full of complexity. One of
the main approaches has been to engage cell-mediated immunity through either using
isolated antigen presenting cells or attempting to stimulate them in vivo. Thwarted by the
relative recent finding of active immunosuppression within the tumour microenvironment a
whole range of new strategies have emerged to circumvent this. Such complexity and
inherent development risk has meant that fewer than one-fifth of oncology biologic
therapeutics in pipeline are vaccines. The upside is the creativity of approaches in both early
and late stage development. The majority of late stage clinical trial promise is focused on
either whole-cell-based autologous or allogeneic tumour cells (off the shelf) approaches, but
the great range, outcome uncertainty and increasing costs make this a high risk area.
Delivery has also been a key technical challenge. As Freda Stevenson and colleagues discuss
in the context of DNA vaccines this has been a challenging area, but novel approaches such
as electroporation, namely using electric charge to ‘force’ the uptake of DNA, may solve the
delivery issue.29 In summary, cancer vaccine development has had a many false starts but
creative approaches and new technologies certainly increase the chance that a winner(s)
will be found in the next five years.
Our next exploration perhaps gives some idea of the vast range and complexity of cancer
immunotherapy. It is arguably one of the most challenging approaches to cancer
immunotherapy and yet is utterly absorbing science. Tumour-targeted oncolytic viruses
(virotherapy with replication-selective viruses) have a range of important features that
make them a viable immuno-therapeutic option, in particular the potential for selective
replication in tumours to increase the therapeutic index, the lack of cross-resistance with
conventional chemoradiation (viruses kill by a numerous other mechanisms) and the ability
to circumvent either tumour or iatrogenic-induced immunosuppression.30 The technical
29
challenges to achieve tumour-selective virus replication are focused around four areas –
limiting the uptake of viruses into tumour cells while ablating the uptake into normal cell
populations, deletion of gene functions that are critical for replication in normal cells,
limiting expression of the E1A gene product to tumour tissues, or using a virus, e.g. reovirus
that is inherently tumour-selective. A whole slew of approaches using adenoviruses,
herpesvirus, vaccinia virus, reovirus et al are in pre-clinical development. Importantly for
such a diverse and complex area, a well-characterised and quantitated virus dl1520 ONYX015 has provided important proof-of-concept data in an early clinical trial setting. While
much has been achieved in this area, for example demonstrating the feasibility of virus
delivery through the blood stream to tumours, major barriers such as the lack of model
systems and potency issues remain.
Finally, there are a whole range of novel approaches to immunotherapy which are not
easily categorised. Immuno-stimulation as a way of directly killing tumour cells and / or
indirectly improving chemoradiation effects is being explored. Rationally designed
approaches utilising MAb have been proposed despite the recent toxicities seen with the
use of the ‘super-agonist’ anti-CD28 MAb (TGN1412) serving as a sobering lesson in the
need for careful and cautious research and development. However, for cancer drug
development biologicals remain a rich and increasingly diverse source for new approaches
2.5. Concluding Remarks
It has been barely fifty years since the cancer clinician had but a handful of
chemotherapeutic agents with which to tackle the huge range and diversity of cancers.
There has been an extraordinary explosion in both our understanding of cancer as a disease
and in the evolution of new molecular entities. Research and development of anti-cancer
agents has become a highly complex, globalised endeavor, and whereas once the private
and public sector ploughed separate paths the needs of cancer science and the proliferation
of the anti-cancer pipeline have slowly but inextricably pulled these ‘two cultures’ together.
This section has provided some sense of the complex science that underpins cancer drug
development. Clearly, this will increase with the molecular stratification of cancers, and
novel prognostic / predictive biomarkers. Policies that understand and evolve complex
systemic approaches to research organisation and management will be essential to deal
30
with the broad church of cancer drug development. The classical linear pathways of R&D are
redundant and a new paradigm is required, one that harnesses the strengths and
opportunities of both private and public sector.
31
References
1. Cufer, T Sullivan R (2008) Researching cancer. Chap 15. In: Responding to the challenge
of cancer in Europe. Ed. Coleman MP, Alexe D-M, Albrecht T. McKee M. Instit. Public
Health Republic Slovenia, 2008.
2. Gelmon, KA, et al (1999) Anticancer agents targeting signalling molecules and cancer
cell environment: challenges for drug development? J NCI 91:1281-87.
3. Hayes AJ, Li, LY, Lippman ME (1999) Antivascular therapy: a new approach to cancer
treatment. BMJ 318:853-56.
4. Pezzuto JM (1997) Plant-derived anticancer agents. Biochem Pharm 53:121-33.
5. Heidelberger C. et al (1957) Fluorinated pyrimidines, a new class of tumor inhibitory
compounds. Nature 179:663-66.
6. Sadee W (1999) Pharmacogenomics. BMJ 319:1-4.
7. Stratford M. et al (2000) Phase I pharmacokinetic and toxicity study of weekly
intravenous combretastatin A4 phosphate. Clin. Cancer Res 6: 280.
8. Baguley BC (2003) Antivascular therapy of cancer: DMXAA. Lancet Oncol 4:141-148.
9. Nauts H, Fowler G, Bogatko F (1953) A review of the influence of bacterial infection and
of bacterial products (Coley’s toxins) on malignant tumours in man: a critical analysis of
30 inoperable cases treated by Coley’s mixed toxins, in which diagnosis was confirmed
by microscopic examination selected for special study. Acta Med Scand 144:S1-103.
10. Dranoff G (2004) Cytokines in cancer pathogenesis and cancer therapy. Nature Reviews
Cancer 4:11-22.
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Cancer Immunol. Immunother 52:297-308.
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4:716-21.
14. Kobie JJ et al (2003) TGFβ inhibits the antigen-presenting functions and antitumor
activity of dendritic cell vaccines. Cancer Res 15: 1860-4.
15. Sangaletti, S (2003) Leukocytes rather than tumour-produced SPARC determines stroma
and collagen type IV deposition in mammary carcinoma. J Exp Med 198:1475-1485.
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targets for the prevention of acquired MDR. Mol Cancer Ther 1:69-78.
17. Mihich E, Harlow E (2000) Signalling cross-talk in cancer cells. Cancer Res 60:7177-7183.
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18. Newell DR et al (2003) Professor Tom Connors and the development of novel cancer
therapies by the phase I/II clinical trials committee of Cancer Research UK. BJC 89:43754.
19. Kaufmann SH (2008) Immunology's foundation: the 100-year anniversary of the Nobel
Prize to Paul Ehrlich and Elie Metchnikoff. Nat Immunol 9: 705-12.
20. Coley WB (1891) II. Contribution to the Knowledge of Sarcoma. Ann Surg 14: 199-220.
21. Hayday et al (2008) Assessing the status of human immunology. Nat Immunol 9: 569.
22. Prestwich RJ, Errington F, Hatfield P, Merrick AE, Ilett EJ, Selby PJ, Melcher AA (2008) The
immune system--is it relevant to cancer development, progression and treatment? Clin
Oncol (R Coll Radiol) 20:101-12.
23. Heng TS, Painter MW (2008) The Immunological Genome Project: networks of gene
expression in immune cells. Nat Immunol 9:1091-4.
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Nat Rev Cancer 6:559-65.
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28. Gilboa E (2004) The promise of cancer vaccines. Nat Rev Cancer 4:401-1.
29. Rice J, Ottensmeier CH, Stevenson FK (2008) DNA vaccines: precision tools for activating
effective immunity against cancer. Nat Rev Cancer 8:108-20.
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Lancet Oncol 3:17-26.
33
3. PUBLIC AND PRIVATE FUNDING FOR CANCER DRUG
RESEARCH AND DEVELOPMENT
3.1. Background and objectives
In policy terms, critical issues around sustainability, productivity and patient impact of
cancer drug development have never been and will not simply be a product of industry.
With such an extensive portfolio of present and future cancer medicines, the funding
contribution of the public sector is absolutely vital. However, public policy decisions around
investment in cancer research need to be anchored in evidence and one of the necessary
key understandings is the source and flow of capital and revenue to support the themes or
domains of research.
A significant number of publications to date on the funding of cancer drug development
and indeed other disease-specific domains have focused on the funding by industry.1,2
Although there is controversy around the use of single numbers,3 there is currently a much
clearer picture of the expenditure by industry on the full development costs of cancer drug
development for policy making. Yet, annualized figures for contribution from the private
sector to cancer drug development specifically are also missing.
A major issue lies in the fact that there are almost no reliable estimates of what the
public sector (philanthropic and federal / governmental spending) contributes to cancer
drug development. Broad-brush policy research has addressed some aspects of public
sector investment, e.g. the US Institutive of Medicine (IOM) review of public sector cancer
funding from the late 1990s4, the mapping of drug development expenditure for public
sector at national level in the UK5 and an updated map of European / USA public sector
spend on general cancer research6, which provide useful denominators. However, data on
how these funds do (or do not) interconnect with private sector (industry) funding or,
indeed, from whom this funding flows and how, are not available (Figure 3.1).
The public sector is both source and sink for a huge range of research activities in cancer
drug development. Furthermore, it is the public sector which mostly trains and hosts today’s
34
and tomorrow’s drug development research faculty, both clinical and non-clinical. Broadly
speaking, there are two major sources of public sector funding for cancer drug
development, first, philanthropic (which can again be sub-divided into endowed charities,
e.g. the Wellcome Trust, and annual fundraisers, such as Cancer Research UK) and, second,
federal (through either federal funding organisations or ministries e.g. BMBF in Germany, or
as general infrastructure funding to host institutions – hospitals/universities sector). In the
latter case, increasingly, major cancer centres and other host institutions are generating
their own sources of revenue and capital for cancer research.
Understanding public and private spending on cancer drug development either to
support direct research costs or through general infrastructural funding is essential so as to
build a coherent picture of the long term health and stability of cancer research and to
understand the future of cancer drug development.
Figure 3.1
The public-private interface in cancer drug research and development
Public-Private Interface
Charities and
Pharma
NGOs
Governments
Biotech
Source: The authors.
35
The objectives of this chapter are to:
1. Understand which major public sector research funding organisations are supporting
cancer drug development and how this is aggregated by country and region;
2. Compare public sector investment by country and region, compare and highlight
which region(s) / countries have committed public sector support for cancer drug
development and which have not. How does this heterogeneity translate to national
and regional strategies in this area, e.g. is the European Innovative Medicines
Initiative building on strong foundations?
3. Explore whether and how cancer research funding flows directly to projects or
indirectly through general infrastructure funds;
4. Quantify the relative contributions of individual countries and understand how this
compares with their overall cancer research spends;
5. Understand the breakdown of public sector funding by the highest common scientific
outline level e.g. cancer treatment development relative to spending in other areas,
e.g. fundamental cancer biology;
6. Outline the relative contributions of charities and NGOs versus governments;
7. Distinguish between the contributions to cancer R&D by political grouping in Europe
i.e. EU member states, accession countries and European Commission;
8. Estimate the annual direct spend by major pharmaceutical companies, stripping away
associated costs up and down-stream, in order to provide a more complete picture of
available funding sources;
9. Explore the public-private interface (Figure 3.1) and how funding flows to cancer drug
development along this critical boundary;
10. Discuss how the sources and sinks of funding compare between countries, and
whether there are policy learning points from those deemed ‘successful’;
11. Determine what trends emerge in terms of overall ‘financial commitment’ to cancer
drug development research, by using high resolution studies of cancer centres, and
the research portfolios of UK, USA and Canada.
36
3.2. Methods
In seeking to extract data from both public sector and industry organisations as to their
funding of cancer research and cancer drug development, a survey of public and private
sector spending on cancer drug research and development was conducted with a view to
obtaining hard data on monies expended on research. Further, in order to provide
background information as well as to compare the present results to those of previous
studies, a literature review was also carried out.
3.2.1. Surveying public sector spending on cancer drug research and development
The inclusion criteria for this part of the survey related to (a) the choice of country, (b)
defining and contacting individual Research Funding Organisations (RFOs) for cancer (c)
classifying the categories of spending for the identified organisations into recognisable
groups to enable comparisons, and (d) distinguishing between direct and indirect cancer
funding.
With regards to country selection, all EU27 Member States together with European Free
Trade Association (EFTA) countries, Israel and Turkey were included as part of the ‘Europe’
region to reflect the breadth of public sector collaborations between countries. Such a
broad number would also allow a sub-analysis of different R&D systems. The USA was also
included in the analysis.
With regards to RFO for cancer, they were defined as those public sector bodies with
spending over one million Euros per annum, as below that level there were estimated to be
over 1,500 smaller charities in EU15 alone. These organisations were classified according to
whether they were a “federal” (governmental) funder or philanthropic. Federal funders
could be either ministries or arms-length government funding bodies, whereas
philanthropic organisations would be either annual fundraisers or endowed charities. The
identification of the organisations was based on broad studies of the public funders of
cancer research across Europe7, the USA4 and, more recently, Canada.
Definitions for categories of spending e.g. cancer control, biology, treatment etc, were
derived from the International Cancer Research Portfolio definitions. The International
37
Cancer Research Portfolio (ICRP) enables direct access to cancer research information.
Cancer research funders from several countries have joined in a partnership to classify their
research portfolios in a common manner. Using the Common Scientific Outline (CSO) as a
unified classification system, the ICRP allows users to search and view cancer research in a
variety of ways, including by type of cancer, by area of research and by funding
organisation.
A distinction was also made between direct and indirect cancer research funding. Direct
cancer research funding was defined as funding originating from RFO to specific host
institutions in the form of grants. It does not include educational grants, non-research staff
salaries, physical plant improvements, spending on advocacy and service delivery. Indirect
cancer research funding is funding derived from general taxation allocated to support host
institution infrastructure and is usually given as a block general grant by government
authorities.
A standard procedure was followed for surveying the RFO for self reported spending on
cancer drug development involving five distinct steps, as follows:
First, letters were sent to the Directors / CEO’s of each RFO requesting funding data for
2007/08. The letters provided a full explanation of the project. As most RFOs are obliged to
provide public figures for spending and had been cultivated there were no outright
rejections.
Second, RFO websites were interrogated to ascertain whether self reported figures
matched published figures.
Third, when received, the requested financial information was reviewed and crosschecked. Guidelines were established to help with this quantification, and were followed
through the entire data collection and data entry phases.
For instance, if a funding
organisation reported spending levels between two amounts, the higher amount was
always used. Any RFO reporting spend in currencies other than Euro had the reported
amount of spend converted using the web site www.xe.com, all currencies were converted
within two days of receipt of the information.
Fourth, the US spending on cancer drug development was based on RFOs identified
previously.8 Many RFOs in the USA such as the Department of Defense and the National
38
Cancer Institute, report their cancer research expenditure in annual reports and a
breakdown of spend by specific intervention, i.e. cancer drug development. Furthermore
the RAND Corporation’s RaDiUS (Research and Development in the United States) database
was also interrogated.9 The database identifies by agency all intramural and extramural
projects or tasks in which the search criteria appear in the title or abstract.
The following terms were used during the relevant search of the database: (a) cancer
drug development and (b) new active substance, new molecular entity (including biologicals
and new chemical entities as cross check MESH terms). These were believed to have the
widest possible chance of collecting all relevant spending, without including projects out of
the scope of interest of this survey. The abstracts of the projects were reviewed to extract
projects that were not focused on cancer drug development (such as when cancer was only
listed as criteria for exclusion in the study).
Fifth, certain cancer RFOs in the USA, UK and Canada belong to the ICRP, a very high
resolution coding of spending against domains of cancer research. This database was
interrogated for project spending levels / activity by the main funders of these countries.
3.2.2. Private sector contribution
Finally, in order to provide a more complete picture and given the fact that the private
sector, i.e. pharmaceutical and biotechnology firms, are major investors on cancer research
and particularly on cancer drugs, we also gave estimates for the annual direct spend by
major pharmaceutical companies.7
3.3. Findings
The challenging and complex task of developing new ground-breaking medicinal
therapies for cancer relies on a collective and multifaceted effort of both public and private
investment into cancer R&D.
Funding for cancer research comes from a complex network of private and public
organisations and from a broad church of commercial enterprises to philanthropic causes.
39
Understanding ‘source to sink’ for cancer research funding is essential for the development
of institutional and national policy-making. In cancer drug development, there are three
broad domains for this funding:
1. The basic research that underpins the discovery of new targets and molecular
entities against these targets, as well as the fundamental biological processes that
drive cancer;
2. The clinical development phase, including biomarker and associated translational
research; and
3. The post marketing phase as new drugs are further developed in new regimens, in
combination with radiotherapy or against new indications.
3.3.1. Public (non-commercial) funding
The majority of cancer R&D globally is carried out within the United States of America
(USA) and the European Union (EU). Research can be funded publicly by the national
governments or regional authorities (e.g. ‘Communidad Autonoma de Madrid), by various
charities and NGOs, or by supranational organisations such as the European Commission
(EC) within the EU. Funding deriving from cancer-specific organisations, is considered as
direct funding and can be either governmental, flowing through either federal funding
organisations or ministries (e.g. BMBF in Germany, INSERM in France and the Netherlands
Genomics Initiative), or philanthropic including charities such as the ‘Wellcome Trust’ (UK),
the ‘Ligue Nationale contre le cancer’ (France) and annual fundraisers such as ‘Cancer
Research UK’ and the Dutch Cancer Society. On the other hand, funding flowing through
from general taxation usually as general infrastructure funding to host institutions – hospital
and / or university sector is considered to be indirect. In the latter case, increasingly, major
cancer centres and other host institutions are generating their own sources of revenue and
capital for cancer research.
In this section, the presentation of the leading cancer research organisations identified
and included in the review will be followed by a series of metrics aiming to capture the
performance of individual countries from different perspectives. The metrics used are (a)
absolute direct public expenditure (investment) on cancer research and drug development,
40
(b) proportion of total public investment on cancer research that goes into drug
development, (c) a comparison between the absolute direct and indirect investment on
cancer R&D in Europe and in the US, (d) per capita direct expenditure (investment) in cancer
research and development, and (e) cancer R&D spend as a percentage of GDP.
(I) Research funding organisations
The inclusion criteria for this part of the survey with regards to:
a. Country selection included the USA and as part of the ‘Europe’ region all EU27 member
states together with European Free Trade Association (EFTA) countries, Israel and
Turkey to reflect the breadth of public sector collaborations between countries. It is
noted that from now on -and unless stated otherwise- the term ‘Europe’ will refer to
EU27 member states, the EFTA countries (i.e. Iceland, Norway and Switzerland), the EU
candidate countries (i.e. Turkey) and the associate states (i.e. Israel). The EU
Commission –and any funding deriving from it- will not be included in that term.
b. Research Funding Organisations (RFO) for cancer included all those public sector bodies
with spending over one million Euros per annum and were classified according to
whether they were a “federal” (governmental) funder, such as ministries or arms-length
government funding bodies, or philanthropic, such as annual fundraisers or endowed
charities;
c. Definitions for categories of spending, e.g. cancer control, biology, treatment etc, were
derived from the International Cancer Research Portfolio (ICRP) definitions classifying
the categories of spending for the identified organisations into recognisable groups to
enable comparisons; and
d. Distinguishing between direct and indirect cancer funding, included as direct cancer
research funding the funding originating from RFO to specific host institutions in the
form of grants. It does not include educational grants, non-research staff salaries,
physical plant improvements, spending on advocacy and service delivery. As indirect
cancer research funding was included the funding that derived from general taxation
and is allocated to support host institution infrastructure and is usually given as a block
general grant by government authorities.
41
In total, 153 non-commercial RFO that satisfied the above criteria were identified across
European countries and 21 in the US and were included in the analysis (Figure 3.2).
42
Figure 3.2
Number of public sector funding organizations by country
Source: The authors.
Apart from these 153 RFOs numerous, other smaller charities exist but were not
included in the survey as their annual spending was less than one million Euros. For
instance, it has been estimated that over 1,500 such charities are operating in EU15 alone.
Their large number and their relative small direct contribution to cancer research made
their inclusion inefficient, if not impossible. Although, this omission may lead to a slight
underestimation of the overall level of public funding on cancer research, the goals of the
analysis (i.e. to built a coherent picture of the long term health and stability of cancer
research and to understand the future of cancer drug development) are still achieved.
It must also be acknowledged that part of the federal funding is indirect, in the sense
spending on hospitals/universities, and even though it is used for cancer research it is not
explicitly earmarked. As a result, the survey mainly addresses direct cancer research
investment and there may be under-estimations on the level of indirect contributions.
Finally, funding flowing in from the European Commission (EC) is likely to be underrepresented, as the annual average during Framework Programme 6 was used and it is
expected that the Framework Programme 7 average will be higher.
43
(II) Summary of policies and organizations supporting cancer drug research and
development in Europe and North America
The European Union
The EC has a number of programmes to help encourage cancer drug R&D. The primary
overall research support programme is the Framework Programme (FP) which provides
funds and support to all areas of research activity in Europe.10 Cancer research is one of
those activities, channeled into the ‘Combating Cancer’ initiative. Previous reports have
criticized EU cancer research with its fragmentation and diversity, as well as different
support mechanisms and funding bodies. Recent action has been proposed from the EC
with ‘Action Against Cancer’, with financial support from the FP, as well as further support
from the European Research Areas (ERA) whose objectives include forming partnerships
between EU, national and regional research programmes, activities and policies.11 As a
result, the previous FP6 (2002-2006) invested some €480 million to 108 transnational cancer
research projects, while the current FP7 (2007-2013) has to date invested €265 million to 65
projects and 700 research groups (one-third to large transnational projects), with more
monies allocated in the future (Table 3.1).
The FP6 promoted research activities with longterm impact which strengthened
Europe’s general scientific and technological basis. In particular, funds were invested where
European cooperation was seen to have significant benefit, striving for EU level research
with many areas and levels of integration. This integration and broader longitudinal view
were new compared to previous FPs. The FP7 continues along this same principle, with
even greater interest in EU level cooperation and coordination of research activities.
Due to this transnational focus, many of the previous FP6 and current FP7 funded
projects encompass many countries and research institutes (Box 3.1). Previous FP5 (19982002) research focused on molecular mechanisms underlying cancer, while FP6 and FP7
focus on translational research, to bring basic knowledge into practice more quickly (Boxes
3.1, 3.2). The FP6 funded EUROCAN+ PLUS project (€5 million budget) aimed to improve EU
research co-ordination, bringing together the Karolinska Institute, Institute Gustave Roussy,
Instituto Europeo di Oncologia, ministries and foundations.
Further support for research
coordination is brought by the ERA Networking project (ERA-Net), focusing on coordinating
national and regional research organisations.
44
Another major EC programme which encourages cancer drug research and development
is the Innovative Medicines Initiative (IMI), a public-private partnership focused on speeding
up the process of drug discovery and treatment.14 This initiative is a collaboration between
the EC and the European Federation of Pharmaceutical Industries and Associations (EFPIA),
with the EC supporting research and development for Academic as well as Small to Medium
sized enterprises, while Large Biopharma fund themselves, with equal support from each
partner. The IMI have a new focus, the Joint Technology Initiative, to support public-private
research cooperation for faster development of new medicines by addressing key
bottlenecks in the drug development process (Table 3.1).
15, 16
The IMI is managed by an
autonomous body in Brussels, with half the governing board comprised of EC members and
half by industry, with industry setting the first round of priorities.
Box 3.1: Examples of transnational cancer research projects in the EU under FP717
GENINCA: to examine cancer genome instability, in the hopes of leading to novel
targeted cellular cancer treatments (11 partners in 8 countries; €3 million 2008-2011)
ERA-NET: to increase cooperation and coordination of research, including cancer
research, activities throughout the EU by networking national and regional level activities
and mutual opening of national and regional programmes (€2 million 2009)
INFLA-CARE: to develop innovative anti-inflammatory strategies and novel agents for
cancer prevention and treatment by studying inflammation driven cancer (20 partners in 9
countries; €12 million 2009-2014)
ADAMANT: to generate superior anticancer agents relying on antibody-based delivery
of cytotoxics, radionuclides or immunostimulatory cytokines to vascular tumour antigens
or tumour cell membranes (€3 million; 8 partners in 6 countries)
45
Box 3.2. Examples of FP6 transnational cancer research projects in the EU, under
Framework Programme 6 (FP6).a, a 12, 13
EUROCAN+PLUS: to coordinate European national cancer research activities after initial
consultation found significant fragmentation, poor leadership and poor sustainability as
major barriers to innovative cancer research. Research duplication, wasting time and
money, limited intellectual concentration, poor communication and tensions between
funders and researchers were seen as additional obstacles. The project recommended to
creation of an independent European Cancer Initiative (ECI) assuming responsibility for:
· Stimulating innovative cancer research and facilitate processes
· Common voice for cancer research
· Interface between public and private cancer stakeholders
· Develop solutions to eliminate collaboration and coordination barriers
· Regulatory and legal issues
This ECI should have a platform for translational research encompassing:
· Coordination between basic, clinical and epidemiological approaches
· Formal cooperation agreements between cancer centers and research laboratories
throughout EU
· Networking between EU funding bodies
Creation of the ECI has yet to be developed (Aug 2009).
ATTACK: to improve engineered T-cell function and perform pre-clinical trials, with the
potential application of gene therapy treatment (17 partners in 8 countries; €11.9 million
2005-2010).
CANCERIMMUNOTHERAPY: to develop a therapeutic cancer vaccine with defined
tumour antigens, refining vaccinations and combining vaccines with other cancer
treatments (22 partners in 8 countries; €12.2 million 2006-2010)
TRANSBIG: to develop individualized breast cancer treatment, to facilitate translational
breast cancer research and to organize a clinical trial examining tumour genetic signature
for use in targeted treatments (40 partners in 22 countries, €7 million 2004-2011)
A new initiative, European Action Against Rare Cancers, has recently been announced by
the EC, as part of their ‘Action Against Cancer’ initiative.18 This focus will be on rare cancers,
both in prevention and treatment, with goals to be determines in the fall of 2009. All but
the major 5 cancers (breast, colorectal, prostate, lung and bladder cancers) are classified as
rare disease (<5 patients/10,000 population).19
Another organization in Europe is the European Organisation for Research and
Treatment in Cancer, whose aim is to stimulate translational and clinical research in Europe.
This organization is funded via various cancer charities in Europe, the FP, industry, and the
NCI, primarily for clinical trials.
46
The USA
The National Cancer Institute (NCI) in the US is the main source of cancer research funds
in America. The NCI is part of the National Institute of Health and the US Dept of Health and
Human Resources, established in 1937 as part of the National Cancer Institute Act, and
receives its funds from the US Congress.20 The 2008 budget included a 1% increase from
2007, and 43% was allocated to 5,380 Research Project Grants and 15% to intramural
research (Table 3.1).21 The NCI has a specific Drug Development Platform which supports a
variety of drug development initiatives, from speedier entry into the marketplace to robotic
high-throughput screening allowing fast biochemical, genetic and pharmaceutical testing
(Box 3.3).
Box 3.3: Examples of national cancer research projects supported by NCI
(USA).22
·
Molecular Targets Development Program identify and evaluate potential molecular
targets for drug development
·
Chemical Biology Consortium accelerates discovery and development of first-in-class
targeted therapies, choosing high-risk targets of low interest to pharma industry
·
Rapid Access to Intervention Development (1998) creates bridges between academic
discovery and clinical trials, as well as supporting investigations into orphan diseases.
To date, RAID has supported 133 projects, resulting in 21 small molecule and 25
biological investigation new drug approvals.
·
Phase 0 clinical trial development, where low doses of investigational drugs are given
to few patients in order to determine whether further investigation is worthwhile.
·
Advanced Technology Partnerships Initiative (ATPI) new research facility to
encourage collaborations between public, private and academic stakeholders.
·
Office of Biorepositories and Biospecimen Research to ensure high quality human
specimens available for research and the creation of a non-profit national biobank.
·
Action as broker between various public and private investors in clinical trials (Life
Sciences Consortium) to ensure speedy contract negotiations (which can cost
companies greater than $1 million in delays, and take between 180-300 days). The
LSC has created a Master Agreement template in 2008 (freely available online) to
minimize contract delays due to language, now supported by the Department of
47
Box 3.4: Examples of activities supported by the NCI International Portfolio22
·
German trial of radio-immunotherapy for NHL, the radioisotope bismuth-213 was
provided by the NCI through a Material Transfer Agreement
·
National Cancer Institute of Canada (NCIC) participates in the NCI Clinical Trials
Cooperative Group Program. Currently, more than 90% of investigational drugs
shipped internationally by the NCI Cancer Therapy Evaluation Program are sent to
Canada – some of these are included in Phase II trials, the only country to do so outside
the US.
·
International clinical trial, led by the NCIC Clinical Trials Group, on letrozole (Femara Novartis) to reduce the risk of breast cancer recurrence. Patients registered in the
trial come from: Canada, US, UK, Belgium, Ireland, Italy, Poland, Portugal and
Switzerland.
·
Collection of more than 50,000 plant specimens from Africa, Madagascar, Central and
South America, Southeast Asia for the NCI Developmental Therapeutics Program.
·
Support to International Center for Studies of Traditional Chinese Medicine,
partnering the University of Texas with Fudan University in Shanghai.
·
Support for the AIDS Malignancy Consortium to pursue clinical trials in resource poor
settings
The NCI also supports international research via its International Portfolio, supporting
cancer research activity in both developed, transitional and developing countries.22 The
activities range from acting as liaison between entities, supporting training and education,
organizing global clinical trials and collecting information about experimental drugs and
protocols with global collaborators (Box 3.4).
Further support for cancer drug research in the US is given by the Foundation for the
National Institutes of Health, established by the US Congress to support the National
Institute of Health via public-private partnership. It is a non-profit organization raising
private funds to support NIH’s public actions, including drug research and development.
The UK
The main cancer research agency in the UK is the National Cancer Research Institute
(NCRI), whose new focus in medicine development is translational research (Box 3.5). The
NCRI works with industry, developing relationships and collaboration with private
enterprise. A number of companies are involved in various NCRI boards, and the NCRI
48
portfolio now includes 34 clinical trails with 17 different companies with likely increases in
the future.
The Medical Research Council (MRC) in the UK is an additional source of cancer drug
development funded by the Department for Innovation, Universities and Skills.23 The MRC
works with the National Institute for Health Research, as well as having close ties with
industry, recently increasing expert industry board members. It has recently joined with
Cancer Research UK, the Wellcome Trust and University of College London to form the UK
CMR International, bringing academics, clinicians and industry together to build a worldclass cancer research institute (building complete 2014).24 Their Drug Discovery Group
(DDG) includes cancer research as a main focus, and includes therapeutic antibodies
(Therapeutic Antibody Group) and kinase programme (Protein Phosphorylation Unit)
research. They also collaborate internationally with other EU and global cancer research
agencies.
Box 3.5: Examples of UK cancer research activities supported by the NCRI.25, 26a, a
Oncology Information eXchange (ONIX): launched in July 2009, which allows the public,
scientists and physicians to search and access global online research data in order to
encourage the flow of cancer research information between vested bodies (£2.5 million,
2003-2010).
National Cancer Research Network (NCRN): supports cancer clinical trials in the National
Health Service (NHS) to improve coordination, intergration, quality, inclusiveness and speed
of cancer research. Currently 11.2% of cancer patients are now entered into clinical trials,
now supported by 33 Cancer Research Networks which are integrated with Cancer Services
Network (£150 million, 2001-2011).
Experimental Cancer Medicine Centres (ECMC): aims to expand the experimental cancer
medicine portfolio and to attract industry-sponsored experimental cancer medicine. It is
funded by the Department of Health and led by Cancer Research UK. It consists of 17
centres, and 2 in development, throughout the UK, with each centre receiving £2.5 million
annually (£35 million, 2007-2012)
Confederation of Cancer Biobanks (onCore UK): systematic collection of cancer
biosamples organized by the Department of Health, Cancer Research UK and Medical
Research Council (£5 million, 2008).
Canada
In Canada, the two main cancer research bodies are the Canadian Foundation for
Innovation and Canadian Institute of Health Research.27 Together they fund over 50% of
49
cancer research, the remainder funded by 33 different agencies, including provincial,
federal, voluntary and multi-funded organizations, which together invested $390 million
(CDN) in 2006. The Canadian Foundation for Innovation is an independent organization
created by the Government of Canada to fund research infrastructure in order to assist
universities, hospitals and non-profit research agencies in performing excellent quality
research, including cancer research.28 One such project is the Canada-California Strategic
Innovation Partnership Initiative, a public private partnership, targeting cancer stem cell
research.
The Canadian Institute of Health Research is composed of 13 Institutes, the Institute for
Cancer Research (ICR) being relevant.29 They support the Canadian Clinical Trials Group
which carries out oncology clinical trials across Canada via 90 member institutions (Phase IIII). In addition, they began the Strategic Training Initiative in Health Research (STIHR) which
supports research training as well as cross-collaboration with other disciplines.
Germany
The main German cancer research organization is the German Cancer Research Centre
(Deutsches Krebsforschungszentrum, DKFZ), which is the largest biomedical research
institute in Germany, and focus on cancer research as well as patient information services.30
The centre is funded primarily by the government, both federal and state, and donations.
France
France has two main cancer research organizations, the National Institute for Cancer
(Institut National du Cancer, INCA) and the Association for Cancer Research (Association
pour la Rescherche sur le Cancer, L’ARC).31 INCA has two main goals to develop cancer
expertise and to develop scientific oncology programmes, in order to address public health,
quality of care, information dissemination and conduct scientific research.32 Financing
comes from public-private partnerships, government and public sources.
L’ARC has
supported over 7,500 research projects over the past 6 years, primarily on cellular and
clinical research.
50
Other
Other organizations in Europe include the Danish Cancer Society, Swedish Cancer
Society, Finnish Cancer Organisation, Spanish Cancer Association, Italian Medical Oncology
Association, Norwegian Cancer Society, Swiss Institute for Cancer Research, Dutch Cancer
Institute (NKI), and a number of others.
Also very important to consider are cancer charities which contribute significant private
funds and vision to cancer research. As these monies can be significant, and in many
instances greater than national cancer research funding, their role in providing advances in
cancer treatment cannot be ignored. In some instances, funds are allocated outside of the
home country’s charity, while others are allocated only to national research.
Overall
The diversity of organizations associated with cancer research is large, often with
significant overlap or duplicity in purpose. Most organizations are specific only to a certain
country (ie Danish Cancer Society) or region within a country, while others are true only to
specific disease (ie Children’s Oncology Group Soft Tissue Sarcoma Committee) even as far
as a specific disease in a region of the country (ie Quebec Breast Cancer Foundation). It is
estimated there are over 120 cancer organizations in Europe, Canada and the US that
participate partially or solely in cancer research.
Although this diverse representation of research, as well as national or regional, aspects
are understandable, the result may be duplication and fragmentation. Administrative costs
are duplicated, available funds for similar purposes are split and the cancer research ‘voice’
may be weakened. The Framework Programme in Europe seeks to rectify this somewhat,
however, has been criticized for adding yet another layer of cancer research bureaucracy.33,
34,
Recently, it has been discussed that EU level leadership on cancer research needs to be
improved and strengthened as well as improve partnership with industry in order to foster
innovation.35
51
Furthermore, differences in national laws can provide a further barrier to performing
transnational research.36 For example, tissue sample banking in one country may be ‘opted
in’ while another ‘opted out’. Data protection and anonymity is another hurdle, particularly
where long-term follow-up is necessary. Even the designation of medical specialties is
universal, there are a number of countries without the medical oncology specialty (falling
under internal medicine domain).
The sparse combination of research and medical
speciality (MD PhD) is also a barrier to cancer research. Although in the US this combination
exists, in Europe this combination is rare.
The EU introduced a Clinical Trials Directive in 2004, designed to harmonize clinical trials
in Europe, however, it has been criticized for increasing the bureaucracy and creating
another barrier for clinical trials to occur in Europe. In the UK it has been held responsible
for decreasing clinical trials activity,37 while in Europe overall it is a factor in longer trial
regulatory procedures.38 Particularly for childhood cancers, it has been seen as responsible
for difficulties in recruitment, increased insurance costs and difficulties between countries in
interpretation and direction of trials.39 It will be reviewed in 2010.
52
Table 3.1
Synopsis of policies and programmes encouraging cancer drug development globally
Programme
Framework
Programme 6
(2002-2006)
Country
EU
Framework
Programme 7
(2007-2013)
EU
Innovative
Medicines
Initiative
EU
Purpose
To develop improved patient-oriented strategies for combating cancer –
from prevention to more effective and earlier diagnosis, and better
treatment with minimal side effects, specifically:
Establishing facilities and developing initiatives for the exploitation of
research ion cancer in Europe
• Evidence-based guidelines
• Accelerate translation of research into applications
Supporting clinical research
• Validate new and improved interventions
• Clinical trials
Supporting translational research
• Apply knowledge in clinical practice and public health
Other issues related to cancer (regional, palliative care, support groups)
Biotechnology, generic tools and technologies for human health
• Includes innovative therapeutic approaches and interventions
Translating research into human health
• Includes translational research in cancer and rare diseases
Optimise delivery of health care to citizens
• Includes pharmacovigilance, benchmarking, better use of medicines
Cancer focus in the overall Joint Undertaking is on:
· Development, evaluation and qualification of imaging biomarkers of
tumour cell development and death, AND of invasive phenotypes
· Creation of imaging centre network to allow clinical validation of
imaging biomarkers across multiple sites
· Improved drug efficacy via target validation, improved modeling and
53
Finance
€17,883 million Total
with €2,514 million Life Sciences
with €485 million Cancer
Research
2007-2009: €265 for cancer
research
2010 call includes €620.5 for
biotechnology and translational
research for which cancer
research will be eligible.
2007-2013 budget: €2 billion,
with equal contribution by EC
and Pharma.
IMI JU 2009 expected budget:
€160 million
European Action
Against Rare
Cancers
EU
National Cancer
Institute
USA
integrated bioinformatics to generate testable hypotheses
· Molecular biomarkers for acceleration of cancer treatment
development, characterization of predictive, prognostic and
pharmacodynamic biomarkers
Cancer focus in the Joint Technology Initiative which addresses research
IMI JTI 2009 budget: €246
bottlenecks (predictivity of safety evaluation, predictivity of efficacy
million (15 projects)
evaluation, knowledge management, education and training):
· Non-genotoxic carcinogenesis, examining the role of early biomarkers
in prediction of cancer development
· Qualification of translational safety biomarkers
· Strengthening the monitoring of benefit/risk of medicines
· European Medicines Research Training Network
· Pharmacovigelance training programme
· Pharma training programme
· Safety sciences for medicines training programme
Partnership in formations, key objectives to be announced fall 2009:
TBA
· Health promotion and early detection of cancer
· Identification and dissemination of good practice in cancer care
· Priorities for cancer research
Coordinates the National Cancer Program, conducting and supporting
2008: $4.83 billion
research, training, health information dissemination for the cause,
diagnosis, prevention, treatment and rehabilitation of cancer:
· Research activities both public, private, academic and in its own
laboratories in all areas of cancer research
· Education and training in cancer research
· National network of cancer centres
· Provides cancer information for public, patients and professionals
· Collaboration with other cancer research organizations, public and
private, as well as industry
54
National Cancer
Institute:
International
Portfolio
USA
Foundation for
the National
Institutes of
Health
USA
Canadian
Foundation for
Innovation
Canada
Canadian
Institute for
Health Research
Canada
National Cancer
Research
UK
Global partnership with a wide range of countries and activities:
· Liaison office in Brussels
· Active and passive representation on cancer research boards,
including Organisation for Research and Treatment of Cancer
(EORTC), Council and Cancer Research UK (CRUK), European Drug
Development Network (EDDN), Southern Europe New Drugs
Organisation (SENDO) and International Network for Cancer
Treatment and Research (INCTR)
· Global clinical trials, training foreign scientists, foster interactions
between scientists
Supports public-private partnership via the National Institute for Health.
Cancer is one of four focus areas in the Biomarkers Consortium, the
others being immunity and inflammation, metabolic diseases and
neuroscience. This consortium is sponsored by 22 companies and 38
non-profit organizations.
Foster knowledge, scientists and entrepreneurial advantages by funding
up to 40% of a research project’s infrastructure costs:
·
Research Hospital Fund (RHF) contributes to large-scale hospital
based research including Large-Scale Institutional Endevours (LSIE)
and Clinical Research Initiatives (CRI)
· Leaders Opportunity Fund (LOF) to assist Canadian universities
attract and retain outstanding scientists
· Leading Edge Fund (LEF) encourages collaborative multidisciplinary
approaches for high tech developments the CFI has previously
invested in. Related, the New Initiatives Fund (NIF) supports
infrastructure for activities not previously invested in.
Creation of new knowledge and its translation into health services and
products. Specifically, for cancer (CIHR-ICR) there are 8 priorities
including: palliative care, molecular profiling, clinical trials, early
detection, prevention, imaging, quality of care and research training.
Partnership between government, charity and industry promoting
55
2008: $86.2 million total (92%
for research partnerships)
Total: $5.4 billion CDN (19982010)
Cancer specific: $80.4 million
CDN (2006)
Total $700 million CDN (200506)
Cancer: $126.4 million CDN
(2006)
£1.6 billion (2002-2006)
Institute (NCRI)
cooperation between 21 member organizations. Specifically the NCRI:
· Maintains a Cancer Research Database
· Develops research initiatives on specific topics
· Coordinated clinical trials (NCRN) and experimental cancer medicine
(ECMC) research
· Develops research facilities and resources
56
Medical Research
Council
UK
German Cancer
Research Center
Germany
Association for
Cancer Research
France
National Cancer
Institute
Swedish Cancer
Society
France
Sweden
Finnish Cancer
Organisation
Finland
Danish Cancer
Society
Denmark
Dutch Cancer
Institute
Netherlands
Support basic and applied medical research in the UK and in Africa,
£682 million (2007)
with the mission of:
· Encouraging high-quality research
· Producing skilled researchers to advance medical knowledge and
technology
· Promote medical research discussions with the public
Seven areas of research focus: cell and tumour biology, structural and
functional genomics, cancer risk factors and prevention, tumour
immunology, imaging and radiooncology, infection and cancer, and
translational cancer research.
Five research areas: Immunology, microbiology, hemotology (22%);
€281 million (2002-2008)
Genetics (26%); Cellular biology (22%), Cellular metabolism (19%);
Diagnosis, treatment, prevention and epidemiology (11%)
Focus on translational research, genetics and cellular research
€44 million (2008)
Independent non-profit, largest financier of national cancer research
funded primarily by private donations (360 million kronar 2006),
providing funds for cancer research, information dissemination, cancer
advocacy,
Consisting of the Cancer Society of Finland, Finnish Cancer
Foundation, Finnish Foundation for Cancer Research and the Foundation
for the Finnish Cancer Institute; private, non-profit funder
Funds the Institute of Cancer Biology focused on the biological
mechanisms underlying cancer, participate in translations research, FP7
funded projects and part of European comprehensive cancer research
centres
Undertakes basic, translational and clinical cancer research
Source: The authors.
57
300 million kronar (2007)
€3 million (2005)
214 DK (2008)
€4.8 million (2008)
(III) Variation in spending by nation
(a) Direct cancer research funding
The 153 European public funding organisations spent altogether €2.79 billion on
oncology research during 2006-2007. Moreover, the 21 US public funding organisations
spent €5.8 billion during the same period (Figure 3.3).
It is, therefore, obvious that the USA dominates in terms of absolute direct expenditure,
investing in cancer research more than double the combined investment of European
countries. Still, it must be noted that the European figure is likely to be an underestimate as
it does not include EU funding by bodies such as the European Commission estimated to
have invested on average €90 million per annum during FP6.
The results further suggest that there is a wide variation in direct funding among
different nations. In Europe the highest single source of public funding was the UK with €1.1
billion expenditure. Germany, France and Italy also invested significant amounts, which
when put together, amounted the same as the UK. From the countries included in the
survey only Malta reported no direct investment in cancer research, while Bulgaria failed to
report on any expenditure.
Another interesting finding is that drug development accounts for a relatively large part
of direct public investment (Table 3.2). However, this excludes late stage clinical
development and, furthermore, much of this funding is focused on pre-clinical
development.
58
Figure 3.3
Direct cancer drug R&D (Spending on log scale)
Source: The authors.
Table 3.2
Drug R&D as percentage of total direct spending
Nation
% of Total Direct Spend
Austria
Slovak Republic
Portugal
Israel
Denmark
USA
UK
Spain
Ireland
Belgium
88.24
60.87
43.24
37.50
30.30
28.94
27.63
27.27
21.05
20.90
Nation
Switzerland
Italy
Sweden
Norway
Netherlands
France
Finland
Greece
Germany
Source: The authors.
59
% of Total Direct Spend
20.37
18.88
18.35
18.18
17.36
17.22
16.84
15.56
13.62
(b) Indirect cancer research funding
From previous funding surveys7 it was clear that, particularly in Europe, significant levels
of support for cancer research flow from general taxation into R&D support for hospitals /
universities. Through the interrogation of major EU countries and reverse engineering using
bibliometrics, the level of this ‘indirect’ funding supporting cancer drug development in the
public sector both in Europe and the USA was estimated for 2007 (Figure 3.4).
Figure 3.4
Estimated indirect cancer R&D funding
(c) Per capita direct spending for cancer research
Reviewing total public sector direct funding per capitao demonstrated substantial direct
funding by the USA (€19/capita) and UK (€18/capita) (Figure 3.5). Scandinavian countries
and the Netherlands are also strong supporters of cancer research with Sweden, the
Netherlands and Norway investing €12.1, €8.8 and €7.2 per capita respectively. In absolute
terms, apart from leading USA and UK funding, substantial European funding derives from
remaining large Western European countries (Germany, France, Italy and Spain) (Table 3.3).
o
Population and GDP figures from UN. 2007e. World Population Prospects 1950-2050: The 2006 Revision. Database.
Department of Economic and Social Affairs, Population Division. New York. Accessed July 2009.
60
Figure 3.5
Cancer R&D direct spending (€) per capita
Source: The authors.
Table 3.3
Top-10 public spenders on cancer R&D per capita vs. absolute spending
Per Capita Spend (€)
Top 10
Direct Public Spend for
Countries
Cancer Research
1. USA
19.34
2. UK
18.34
Absolute Spend (€ million)
Top 10
Direct Public Spend for
Countries
Cancer Research
1. USA
5799
2. UK
1104
3. Sweden
12.1
3. Germany
426
4. Netherlands
8.83
4. France
389
5. Switzerland
7.30
5. Italy
233
6. Norway
7.17
6. Netherlands
144
7. France
6.38
7. Sweden
109
8. Belgium
6.44
8. Spain
77
9. Germany
5.15
9. Belgium
67
10. Greece
4.05
10. Switzerland
54
Source: The authors.
61
Regarding drug development, the US and the UK remain leaders, both investing more
than €5 per capita for drug development. Additionally, eight more European countries
spend at least one Euro per capita on drug development (Table 3.4). In absolute terms, large
Western European countries dominate in drug development funding as they did in the case
of overall cancer research.
Table 3.4
Top-10 public spenders on cancer drug R&D per capita vs. absolute spend
Per Capita Spend
Top-10
Countries
Absolute Spend
Direct Public
Spend for Cancer
Drug Development
(€ per capita)
5.60
5.07
Top-10
Countries
3. Sweden
2.22
3. France
67
4. Denmark
1.85
4. Germany
58
5. Netherlands
1.53
5. Italy
44
6. Switzerland
1.49
6. Netherlands
25
7. Belgium
1.35
7. Spain
21
8. Norway
1.30
8. Sweden
20
9. France
1.10
9. France
14
10. Ireland
0.98
10. Switzerland
11
1. USA
2. UK
1. USA
2. UK
Direct Public Spend
for Cancer Drug
Development
(million €)
1678
305
Source: The authors.
The USA and UK have a long history of public sector support of cancer drug development
(Table 3.5). In the USA this has been in place since the early days of the National Cancer
Institute (NCI) and has formed a major backbone of its strategy through a variety of funding
streams both direct project related and infrastructural. In the UK cancer drug development
in the public sector has enjoyed a major philanthropic backer and, more recently, increased
governmental support through the creation of the Experimental Cancer Medicine Centres
initiative (ECMC)p. However, apart from the USA and the UK who appear to have a national
p
The major network of Experimental Cancer Medicine Centres (ECMCs) was established in 2006 across the UK
to bring together laboratory and clinical patient-based research to speed up the development of new therapies
and biomarkers by evaluating new drugs and individualizing patient treatment. It is a joint initiative between
62
strategy on cancer drug development, overall the levels of funding per capita do not appear
to equate with any coherent national strategy on cancer drug development, rather these
levels reflect an ad hoc approach by governmental and philanthropic funders.
Table 3.5
Main funding sources of Europe’s top funding countries (public sector)
Country
Main Funding Sources
Belgium
IWT, Televie
Denmark
Danish Cancer Society, Danish Medical Research Council
France
CNRS, INSERM, Institut Curie, Ligue National Contre le Cancer
Germany
BMBF, Deutsche Forschungsgemeinschaft, Deutsche Krebshilfe
Greece
General Secretariat of Research and Technology
Ireland
Higher Education Authority, Science Foundation Ireland, Health Research
Board
Italy
Ministerio dellÍstruzuione dell’Universitá e della Ricerca, AIRC, Consiglio
Nationale delle Ricerche, Fondazione Italiana per Ricerca sul Cancro
Netherlands
Dutch Cancer Society, Ministry of Health, Welfare and Sport, ZonMw
Norway
Norwegian Cancer Society, the Research Council of Norway
Spain
Instituto de Salud Carlos III – Fis (Ministerio de Sanidad y Consumo),
Ministry of Education and Science
Sweden
Cancerfonden, Barncancerfonden, Cancer-Och Allergifonden
Switzerland
Swiss National Science Foundation, Oncosuisse, SBF
UK
Cancer Research UK, Department of Health, Wellcome Trust
USA
National Cancer Institute, Department of Defense, States, Howard Hughes
Medical Institute, American Cancer Society
Source: The authors from national sources.
When averages are examined, it becomes apparent that Europe fails to match the public
funding levels of the US in cancer research and development. Indeed, the average per capita
spend on total cancer research across the entire Europe was €3.45 while the per capita
Cancer Research UK and the Departments of Health in England, Scotland, Wales and Northern Ireland. See:
http://www.ecmcnetwork.org.uk/
63
spent in the US was €19.34. However this gap is reduced to 3-fold if the US spending is
compared with the spending of the EU15 countries only (average per capita spend €5.64).
Compared to 2004 funding levels1 Europe spend per capita on average in 2007 34.7%
more while the US 9,7% more revealing an obvious trend for Europe to close the existing
gap with the US (Figure 3.6).
Figure 3.6
Direct cancer R&D spending per capita, 2004 vs. 2007 (€)
Source: ECRM (2004 data) and the Authors (2007 data).
(d) Direct spending for cancer research as a percentage of GDP
A similar pattern is evident when one reviews cancer research spend relative to GDP
(Figure 3.7). The average cancer research spend for ‘Europe’ was 0.0143% of GDP, which is
a decrease of 19.2% from 2004 figures (average spend was 0.0177%). The average cancer
research spend in the USA was 0.061% of GDP in 2007, representing an approximate 10%
64
increase over 2004. The European spend is driven by the UK (0.072 of GDP on cancer
research), followed by Sweden (0.048% of GDP).
In the case of drug development, again the UK and the US are investing a larger part of
their GDP than the rest of the countries in the survey.
Figure 3.7
Cancer drug R&D and cancer R&D direct spending, % of GDP
Source: The authors.
65
(e) Cumulative spending for cancer drug R&D
Total public sector support from all research funding organisations and through
hospitals/universities (indirect) identified by this survey for cancer drug development in
Europe and the USA was estimated to be c. €2.8 Billion in 2007/08 (Figure 3.8).
Figure 3.8
Route of cancer drug R&D funding
Source: The authors.
Adding indirect spend for Europe as a whole dramatically closes the ‘gap’ with USA
public sector funding of cancer drug development (Figures 3.9, 3.10). In effect, when both
direct and indirect funding is taken into account, Europe spends 0,011% of GDP into cancer
drug development compared to 0,018% by the USA and €3.64 per capita compared to €5.74
by the USA.
66
Figure 3.9
Cancer drug R&D spend per capita (€)
Source: The authors.
Figure 3.10
Cancer drug R&D spend, % of GDP
Source: The authors.
67
(f) Spending by CSO in Europe
In order to compare and contrast research portfolios of public (i.e. NGOs and
governmental) research organisations using a certified vocabulary, the Common Scientific
Outline (CSO)40 was used quantify cancer research expenditure. The CSO is a classification
system, originally validated by the International Cancer Research Portfolio (ICRP)41 and now
in use by the USA, UK and Canada27, that is used to classify spending around seven broad
areas of scientific interest in cancer research.
One hundred and two research funding organisations were interrogated across Europe
of which 47 returned usable data of self reported percentage breakdown of their annual
spending on cancer research by the highest common scientific outline level.
Briefly, €750.6 million was spent on cancer research by both charities and governmental
research agencies, from which €557.1 million was placed in CSO categories (Figure 3.11).
This dataset found a strong and growing commitment by European funders to
supporting cancer drug development. In nearly all projects there was a complex mixture of
funding sources supporting various components of the research project, whether laboratory
based or clinical. Whilst distinct funding streams do exist from research funding
organizations, once these resources hit the front line then research groups and centers
utilize both private and public financing in a mixed economy to deliver on the group’s or
centers goals.
A high resolution analysis of all projects falling under cancer drug development
(including associated biomarker studies) has also been derived from the ICRP database.
Figure 3.11 shows the distribution of active drug development projects (2007/08) by
research funder in the USA, UK and Canada.q
q
See http://www.cancerportfolio.org/wizsearch.jsp?add=FundingOrg for details on individual funders
including full names
68
Figure 3.11
European cancer R&D spend by CSO category
Source: The authors.
In total, these public sector major RFOs in three countries are currently supporting 5105
cancer drug development projects (591 projects by 14 Canadian RFOs; 455 projects by 9 UK
RFO’s and 4,059 projects by 5 USA RFO’s) (Figure 3.12).
69
Figure 3.12
Number of active cancer drug development projects by funder, grouped by
USA
CRUK
LFR
MRC
DOH
BBSRC
BCC
YCR
RC/TNV
NIR&D
CANADA
NCI
DOD
KOMEN
ACS
CBCRP
EUROPE
country (log scale)
CIHR
TFF
CCS
FRSQ
ACB
CBCF
MSFHR
CRS
OICR
CBCRA
NRC
CCMB
AHFMR
PCRFC
1
10
100
1000
10000
No. Active DD
Source: The authors.
Using the ICRP database, a high resolution study of the major European Cancer centers
involved in drug development has also been conducted to assess Institutional level spend on
cancer drug development relative to other domains of cancer research.
Fundamental biology and research into treatment, of which cancer drug development
accounts for around 82% of the total spend, dominate the research funding allocations by
this sample of major European Cancer Research Centers (Figure 3.13). Research into cancer
drug development is a significant aspect of all those centers’ portfolio and across research
domains we have estimated from this high level coding that circa 36% of all cancer research
activity in major European Cancer Centers is focused on cancer drug development.
70
Figure 3.13
Scatter plot showing percentage of spend according to domain of research (by
CSO category) for a sample of European Cancer Centres (n= 20)
100
90
80
70
60
% 50
40
30
20
10
0
Source: the authors.
(g) Spending by charities versus governments
There are a very large number of charities supporting cancer research worldwide. Some
charitable organisations focus on specific types of cancer and give priority in funding
research related to this specific cancer. Examples of charities falling into that category
included in this survey are ‘Associazione Italiana contro le Leucemie, Linfomi e Mieloma’ and
‘Associazione Italiana per la Lotta al Neuroblastoma’ in Italy which focus on Leukemia,
Lymphoma, Myeloma and Neuroblastoma, ‘Breakthrough Breast Cancer’, ‘Breast Cancer
Campaign’ and ‘Leukemia Research Fund’ in the UK and ‘Prostate Cancer foundation’, ‘The
Leukemia and Lymphoma Society’ and ‘The Komen Breast Cancer Foundation’ in the USA.
These charities are usually smaller and do not fund in absolute terms as much as the
ones that focus on cancer broadly. For instance, the American Cancer Society, The American
Institute for Cancer Research, Cancer Research UK, the Belgian Federation Against Cancer,
71
the Danish Cancer Society, the ‘Association pour la Reserche contre le Cancer’ and the ‘Ligue
Nationale contre le Cancer’ in France, the Irish Cancer Society, ‘Associazione Italiana per la
Ricera sul Cancro (AIRC) in Italy, the Dutch Cancer Society and the BMBF in Germany are
organisations that fund significant amounts in overall cancer research.
In addition, some charities do not focus specifically on cancer as they finance a broad
variety of medical research. However, some invest significant amounts on cancer research
such as the Wellcome Trust42 that represents the largest charity in the UK and the
‘Fundación la Caixa’ in Spain.
In the USA, governmental sources of funding for cancer development dominate mostly
through the National Cancer Institute (NCI) and NIH Research Project Grant Program (RO1)
grants from the National Institutes of Health (NIH). On the other hand, Europe is actively
supported by the philanthropic sector.
In this respect, some countries have well-developed philanthropic and governmental
funders for public sector drug development both in terms of number of funding
organisations and in absolute investment, e.g. UK, Netherlands, France and Germany.
However, most countries are heavily reliant on the private sector to support both individual
projects and some basic infrastructure within the hospitals/universities sector.
In particular, whilst philanthropic funders support a wide range of cancer drug
development projects there appears to be a relative deficit of funding from governmental
sources in Europe (Figure 3.14). In fact, over 50% of non-commercial funding in Europe
derives from the philanthropic sector.
It should also be mentioned that in Europe, for six countries (i.e. Bulgaria, Estonia,
Latvia, Lithuania, Romania and Slovenia) there were no philanthropic funding organisations
for oncology research. In contrast, in Cyprus there was no government R&D funding
organization for cancer.
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Figure 3.14
Drug R&D funding by charities and government (2007)
Source: The authors.
(h) Spending by political EU membership status
Current European Union member states (EU27) contributed more than €2,693 million to
non-commercial cancer research. The accession countries contributed only for the 0.75% of
the total expenditure in Europe. The European Commission (EC), according to the per
annum average during FP6, contributed €90 million to cancer research, although this
number may be underestimating the actual support as cancer research is being funded by
other, indirect streams from the EC (Figure 3.15).
73
Figure 3.15
Percent of direct spend by political group in Europe (2007)
Source: The authors.
3.3.2. Private sector cancer funding organisations
[I] Types of private funding for cancer research
Private/commercial
funding for
cancer
research
derives from the
industry
(Pharmaceutical and Biomedical/Biopharmaceutical industry). Information on industryrelated funding is difficult to determine partly because of proprietary concerns. Moreover, it
is said that marketing and administration costs are often included into the reported R&D
expenditure.8 The private funding focuses primarily on drug development.43
74
[II] Commercial expenditure on cancer research
Various publications have estimated commercial expenditure on cancer R&D using a variety
of sources. In general, there are three different ways to calculate worldwide private R&D
spending:
1.Based on development cost of a new chemical entity (NCE)
2.Based on total R&D expenditure weighted by share of oncology drugs
3.Total oncology and immunomodulant R&D expenditure (e.g. according to CMR
International)
Because the variety of accounting methods used as well as the inclusion of ‘marketing’
expenditure as part of these estimates it has been notoriously difficult to estimate the true
level of disease-specific expenditure.
One novel way to estimate direct cancer-related expenditure using bibliometrics is by
assigning cost per unit of research based on outputs i.e. the proportion of each company’s
published papers that are in cancer research (Figure 3.16). Stated R&D expenditure from
annual reports is considered to be the total R&D cost for each major pharmaceutical
company. However, one issue with this method is that it is likely to underestimate the true
activity of a company in certain areas from which publications do not adequately reflect
output, e.g. early phase clinical trials. We can correct for this relative underestimation to
give a broad picture of direct spend on cancer drug R&D.
75
Figure 3.16
Private cancer drug development spend: major pharmaceutical
Euro (million)
companies (2004/ Phase III)*
Note: *The figure does not include all industry (e.g. SME and biotechnology)
Source: ECRM, 2007.
Total expenditure by 17 major pharmaceutical companies was almost €3,095 million
(2004 figures, reported in 2008). By separating the US-based from the Europe-based
companies, we can get an idea of what proportion of private spending flows from each area
(Figure 3.17). In fact, 59% of the total private cancer R&D funding derived from Europebased companies.
76
Figure 3.17
Euro (million)
Private cancer R&D funding by company origin
Source: The authors.
3.3.3. Public – Private partnerships in cancer drug development
Public-private partnership is strong in both Europe and the USA, particularly in the
former this is growing. Philanthropic and federal funders must recognize and reward these
joint enterprises, particularly in light of the growing complexity and number of the cancer
drug pipeline and associated predictive markers.
The figure below (Figure 3.18) gives a ‘snap-shot’ of recent annual spending from which
we can assess the relative amount of public-private collaboration. Although this only looks
at one metric (i.e. outputs), it nevertheless provides an indicator of the current health of
private-public collaboration in cancer drug development. These measure real collaborations,
i.e. joint intellectual input, but do not take into account projects for which industry have
provided basic infrastructure funding to research units, unrestricted educational grants or
in-kind support (e.g. free drug supply). All these activities could legitimately be put into the
public-private ‘partnership’ category. Furthermore an analysis of the projects detailed in
Figure 3.12 has also been used to estimate the degree to which industry and the public
sector already co-operate on cancer drug development.
77
Figure 3.18
Cancer drug development projects with joint private-public funding (%)
(2007-8)
Source: The authors.
Looking at trends, while the USA and the Rest of the World have been relatively static
since the mid 1990’s, Europe has seen substantial growth in its private-public joint research
projects on cancer drugs. We have also found some evidence (from interviews with key
opinion leaders) to support the fact that the practice of unrestricted grant support appears
a more widespread practice in Europe than the USA.
3.4. Discussion
The burden of cancer has broad consequences which go beyond individuals and their
families to the healthcare systems and economies of individual countries. Therefore, as
human lives are increasingly burdened by cancer, the fight against the disease relies on both
a strong privately and publicly funded research base.
Understanding public and private spending on cancer drug research and development,
either to support direct research costs or through general infrastructural funding, is
essential to build a coherent picture of the long term health and stability of cancer research
and to understand the future of cancer drug development. Any public policy decisions
regarding the setting of priorities and investment in cancer research need to be anchored in
78
evidence, and one of the necessary key understandings is the source and flow of funds to
support research presented in the previous section. Moreover, comparable and reliable
data on ongoing research activity are essential in order to promote and coordinate strategic
planning of cancer research both at national and international levels.
This section discusses the motives behind public cancer research funding and identifies
the emerging trends in terms of overall “financial commitment” to cancer drug
development research. In parallel, it explores how the sources and sinks of funding compare
between countries and whether there are policy learning points from those deemed as
successful. Moreover, the role of the private sector, its partnership with the public sector,
and the national/supranational interface are underlined. Finally, it discusses whether a clear
picture is emerging in forming policy options by highlighting the lack of data, the gaps and
the limitations in our understanding of cancer research funding.
3.4.1. Public Sector Funding
[I] Motivation for publicly funded research
In general, there are two main kinds of motivation for publicly funded research:
The first is the economic motivation that derives from the market failures that
accompany the production of new knowledge. Specifically, the difficulty in establishing
property rights within the process of producing scientific and technological advancements
makes the engagement to such research unattractive to profit-seeking investments.44,
45
Simply put, the probability of spillover effects along with the high risk of failure and the
timely process of creating knowledge are often responsible that basic research is often a
poor target for private investors.
On the other hand, micro level empirical evidence46-50 has shown that the public rate of
return on investment in research to produce such knowledge tends to be many multiples of
the rates for private investors due to positive spillovers to consumers and competitors.
Macro level evidence51, 52 suggests that the growth rate of the economy’s productivity is
associated with the creation and adoption of innovative technology.
Consequently, private investment in types of scientific R&D -such as medical and
biomedical research- is not expected to reach the optimal societal level and therefore,
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public contribution is necessary. One form of intervention is the establishment of firm
intellectual property rights in the form of patents, copyrights, and market exclusivity
periods. Tax subsidies of private research are also common, but such instruments may often
be ineffective as it is hard to target basic-discovery research for which there is underinvestment unless such incentives are targeted accordingly. As a result, applieddevelopment research that could anyway attract enough private funds also winds up being
subsidized.
The above discussion leads to the conclusion that the most reliable tool to assure
socially beneficial levels of R&D is direct funding. Long-term funding programs could also
contribute to the stability of research levels regardless of business cycles in industry or the
economy. In addition, provision of research infrastructure and high-quality training for the
next generation of scientists could lead to further beneficial effects.53
The other type of motivation for public funding of research stems from political and
social reasons. Historically, it has been more likely that political concerns such as national
esteem and defense agenda have been the key incentives of public funding for scientific
research rather than economic ones. Furthermore, social needs have been another
catalyzing driver of public investment in R&D. Diseases such as cancer affect millions of
people every year, place a significant burden on society and, in consequence, the public
demand for the alleviation of such disease-related burden puts a lot of pressure on
governments.
A good example is the NIH (National Institutes of Health) in the US that has been the key
player in the fundamental progress of bioscience, representing the public motivations
through its system of 25 institutes organized around “body systems” (such as the National
Lung Institute), and illnesses (such as the National Cancer Institute). The proportions of the
NIH budget devoted to each health condition reflect that condition’s relative threat to the
US nation. Still, in harmony with Vannevar Bush’s vision (Box 3.1), an extensive peer review
system is employed to allocate each institute’s resources to researchers and research
projects (Box 3.6). Bush’s vision of course is just one of the many different ways the US
government can and does fund scientific research, as shown on Figure 3.19.
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Box 3.6
The Vannevar Bush vision of national science policy
In 1941, Vannevar Bush, former Dean of Massachusetts Institute of Technology
School of Engineering and president of the Carnegie Foundation, was assigned the
management of the Office of Scientific Research and Development by President
Roosevelt. Bush successfully coordinated the application of academic knowledge to
support the war effort leading -among other- to the mass production of penicillin,
the manufacturing of a feasible synthetic rubber and the atomic bomb.
In an attempt to assure the harnessing of such results in the postwar era, Vannevar
Bush described in his influential Carnegie Foundation report “Science: The Endless
Frontier” the establishment of a permanent federal science policy.
According to his vision, basic scientific research including medicine, physical science
and life sciences would be carried out by both state and academic scientists and
would be supported by federal funds.
Bush rejected “economic” motivation and adopted the humanistic argument that
excessive political or commercial direction of scientific research would inhibit the
scientists’ curiosity motives, which he believed to be the most effective. Thus, he
proposed that scientists would be in charge of the fund allocation through the
establishment a peer review system.
To date, the purest application of his ideal is considered the National Science
Foundation, founded in 1950. However, the NHI is itself an example of an -at least
partial- application of his vision.
Source: Lawlor 2003; Bush, 1945.
53, 54
81
Figure 3.19
Interaction between basic vs applied science and between market vs government
Market
Applied
Basic
Science
Science
Government
Source: Adapted from Ruttan 2001.
51
[II] National and supra-national spending
The USA has a well-established national cancer strategy, making the USA the largest
single source of funds invested in cancer research globally (Box 3.7). The direct public sector
spending in 2007 was €5.8 billion, while indirect public spending was estimated at €477
million. In addition, US-based pharmaceutical companies invested €1.3 billion in cancer
R&D. All these figures together result in €7.06 billion of cancer research funding in 2007.
82
Box 3.7
Public Funding Sources for Cancer Research in the United States
In 1971, the National Cancer Act launched the War on Cancer, a disease that apart
from causing suffering and deaths among the Americans also has significant
economic costs. The War on Cancer greatly amplified the priority of cancer research
in the federal budget, and the Act set up a model of public-private collaboration built
around a national net of research laboratories and cancer centers.
The advances in cancer research that followed led to improved screening methods
and better treatments, which along with the greater understanding of risk factors
such as smoking, resulted in bringing to an end the increasing rate of cancer
mortality in 1991.
Today, the USA leads cancer research and drug development and is the largest single
funding source in the world. Indeed, in 2007 €5.8 billion were directly invested in
cancer research just by the non-commercial sector, reflecting the USA’s wellestablished national cancer strategy.
Most of the funding for cancer research derives from federal sources:
The National Cancer Institute (NCI), established in 1937, is the first categorical
institute of the National Institutes of Health (NIH) and also its biggest one. Although
the NCI is not the only NIH funder of cancer research, it is the largest one and
almost all funds dedicated to cancer R&D derive from it. Its annual strategic
research and academic research are openly published but NCI also supports drug
development research. The NCI’s role in R&D includes: (1) the integration of
discovery activities through inter-disciplinary partnerships; (2) the speeding up of
innovations and provision of technology that will facilitate accomplishments of
translational research; and (3) the measuring of the application of knowledge
deriving from these innovations in cancer care, for instance in clinics or public
health programs.
Other National Institutes of Health also support cancer research. The National Lung
and Blood Institute, for example, contribute through its agendas for lung and blood
diseases respectively. The National Institute’s of Environmental Health Sciences
research on biological responses to environmental agents also includes cancer. As
cancer concerns all organs and systems and every age group, each NHI institute and
the majority of centers contribute to some cancer-related research.
Other Department of Health and Human Services Agencies (DHHS) such as the
Centers for Disease Control and Prevention (CDC), the Agency for Healthcare
Research and Quality (AHCPR) and the Health Care Financing Administration (HCFA)
83
spend significant amounts on cancer-related research.
Other Federal Agencies also fund cancer R&D projects. For example, the
Department of Defense (DOD) has become a major source of funds in recent years
for research on breast, ovarian and prostate cancer. Moreover, the Department’s
of Veterans Affairs (VA) research initiatives focus on cancer, among other on
chronic diseases and conditions that affect veterans. Agencies such as the
Environmental Protection Agency (EPA), the Department of Energy (DOE), NASA,
the National Science Foundation (NSF) and Department of Agriculture (USDA) also
fund some cancer research, but their contribution is relatively small.
Public funding also streams from non-profit organisations such as independent
endowments and funds, corporate giving foundations and community-based donors.
Funding deriving from such organisations is tracked by the Foundation Center.
The Howard Hughes Medical Institute is a strong supporter of the biomedical
research and especially cancer-related research.
Voluntary Health organisations such as the American Cancer Society (ACS), the
American Institute for Cancer Research (AICR), the Cancer Research Foundation of
America and the National Foundation for Cancer Research support the fight against
cancer by collecting donations from the general public and by funding apart from
basic cancer research, treatment services and prevention programs. Similarly,
charities that focus on specific types of cancer such as the Leukemia Society of
America (LSA), the Association for the Cure of the Cancer of the Prostate (CaP
CURE) and the Komen Breast Cancer Foundation, contribute a great deal in cancer
research projects.
Finally, several State Governments directly support financially cancer centers or
have established cancer research programs.
Source: Sources of Research Funding in the US / concerning Trends and Outcomes for National Institutes of
Helath Funding of Cancer Research
In Europe, the public sector invested directly €2.79 billion in cancer research in 2007.
Adding to that the ≈€90 million of European Commission Funding, the €1.8 billion spent on
cancer R&D by Europe-based pharmaceutical firms and taking into account the indirect
funding of €1.6 billion that flows through hospitals/universities, it is clear that a strategic
plan to coordinate the allocation of these significant funds is indispensable. The above
figures result in a grand total of €6.28 billion for cancer research funding in 2007, which is
comparable (although slightly inferior) to the sum invested in the USA.
84
The findings of this survey brought to the surface three major facts:
First, there are prevailing gaps in funding between Europe and USA as well as among
European countries and especially between EU Member States themselves. In Europe, most
of the funds are raised and invested within EU15 Member States. Particularly, the UK,
Germany, France and Italy dominate cancer research investment in absolute terms. Yet, in
terms of spend per capita or spend as a percentage of GDP, apart from the UK that supports
cancer R&D with outstanding amounts of funds (Box 3.8), the other major funders were
Sweden and Netherlands.
Box 3.8
Cancer research funding in the UK
Cancer is major health condition in the United Kingdom and as the population ages
and lives longer; it is becoming increasingly a greater burden to the National Health
System (NHS).
In 2007, the United Kingdom’s non-commercial sector invested €1.1 million in cancer
research, an amount that corresponds to more than one third of Europe’s overall
investment. This is consistent with the fact that cancer has long been a national
priority for the UK.
In the UK, cancer research is supported by several different government agencies,
most of which fund medical research in general, rather than having a cancer-specific
focus. The most important funders among these include the Medical Research
Council (MRC)*, the Department of Health (DoH), the Biotechnology and Biological
Sciences Research Council (BBSRC), The Economic and Social Research Council
(ESRC), the Northern Ireland HPSS R&D and the Wales Office of R&D.
Furthermore, what distinguishes the UK from most other countries is the fact that it
has an exceptionally large charity sector. We have indeed estimated that about 250
different charities support cancer research in the UK;
Cancer Research UK†, the result of merging the Imperial Cancer Research Fund and
the Cancer Research Campaign, is the largest non-government cancer research
organisation worldwide. Cancer Research UK collaborates with other charities,
public research organisations and the pharmaceutical industry to better
understand the disease, to improve prevention, diagnosis and treatment of cancer
and to keep cancer a top priority of the national health agenda. During 2007-08,
Cancer Research UK raised £477 million and spent on cancer research a record of
85
£333million.
Other important NGO’s that invest at least £1 million on cancer research in the UK
include: the Association for International Cancer Research, the Breakthrough
Breast Cancer, the Leukemia Research Fund, the Ludwig Institute for Cancer
Research, the Macmillan Cancer Support, the Marie Curie Cancer Care, Tenovus,
Roy Castle Lung Cancer Foundation, Children with Leukemia and Yorkshire Cancer
Research .
As a response to the need for coordination of cancer research and collaboration
among the numerous governmental, non-governmental and private sector funders,
the National Cancer Research Institute (NCRI)‡ was founded in 2001. NCRI brings
together the 20 largest of the charity and government funders, along with industry
represented by the Association of the British Pharmaceutical Industry (ABPI). NCRI’s
role consists in maintaining a strategic overview of cancer research in the UK and in
encouraging greater consistency among the major funders. In order to do so, NCRI
maintains a Cancer Research Database, develops research schemes, assists the
organization of clinical trials on experimental cancer drugs and develops research
facilities and resources (e.g. data management using IT).
*See: www.mrc.gov.uk
†
See: www.cancerresearchuk.org
‡
See: www.ncri.org.uk
The disparities in national spending are even more apparent in the case of the new
Member states that joined the EU during the 2004 and 2007 enlargements. These countries
limit their activities primarily to prevention and awareness programmes (e.g. tobacco
control). The need for further political commitment on cancer research as well as the
development of a specific cancer policy framework is highlighted in order for the whole
enlarged Europe to meet –even with some delay- the target of increasing science and
technology research spending to 3% of the EU’s GDP set at the Lisbon European Council of
March 2000.56
On the other hand, countries such as the USA, the UK and Sweden spend a significant
proportion of their GDP in cancer research (i.e. 0.061%, 0.072 and 0.048% of GDP
respectively), which demonstrates that cancer ranks highly among their socio-political
priorities. Despite the discrepancies among European nations, Europe on average increased
in 2007 the per capita investment in cancer research by 34.7% since 2004, compared to a
86
just 9.7% increase by the USA, illustrating a desire for Europe to close the existing gap with
the USA.
Second, the weight that nations place on cancer drug development and, therefore, into
more applied clinical research, varies significantly. The evidence suggests that public funding
primarily focuses on basic rather than applied research, as the latter is more likely to attract
private funds.
The third issue has to do with cancer research funding at the EU level. The average
annual spend was estimated at €90 million during FP6. It is probably the case that this
amount has been insufficient to cover the research needs of cancerr,.57 However, FP7
(2007/2013) has already been launched and with a cancer research budget set at €5,984
million58 it is expected to improve both the existing cancer research effort and its clinical
applications.
During the FP6 and the first two calls of FP7, around €750 million was allocated to cancer
research. On June 26th, 2009, a EC Communication underlined that most research in the
field of cancer is carried out at Member State level, and hence, is ‘fragmented’.59 In this
direction, the Communication proposed a “European Partnership for Action against Cancer”
which apart from public health measures (e.g. screening) and good treatment practices
recommends additional coordination and collaboration in cancer research. With the
objective to achieve coordination of one third of cancer research from all funding sources by
2013, the Commission proposed the creation of a large stakeholder forum to undertake the
work of the Partnership that will include all kinds of organisations, in the 3rd quarter of
2009. The stakeholder working groups will be based on the following areas of action:
prevention, healthcare, research and information and their work will be coordinated by a
‘steering’ group.
As part of the governmental funding is indirect (i.e. flows through hospitals/universities)
although used for cancer research, it is not clearly earmarked. In consequence, this survey
r
See: http://cordis.europa.eu/lifescihealth/cancer/cancer-pro-calls.htm
87
primarily addresses direct cancer research investment and, therefore, there may be underestimates of the level of indirect contributions. Moreover, there are likely further underestimates of the contribution of several smaller charities with annual spending of less than
one million Euros. For instance, it has been estimated that over 1,500 such charities are
operating in EU15 alone. Furthermore, the contribution of European umbrella bodies (e.g.
the Federation of European Cancer Societies, FECS), relevant patient groups and policy
initiatives for cancer research such as EUSTIR and EURoCAN+Pluss that have some
involvement in cancer research, has also been under-estimated.
[III] Role of indirect and philanthropic funding
In the USA, the NCI alone spent €3.58 billion on cancer research in 2007, an amount
accounting for 62% of the total direct public sector spent in the USA. This is reflecting the
fact that for the USA cancer research is a long-established priority, supported mainly by a
centralist financing model. On the other hand, in Europe, cancer research represents a
different priority for different countries, while its funding is widespread across numerous
diverse funding sources.
Specifically, in Europe, significant funding supports indirectly cancer research flowing
through academia and healthcare systems (e.g. only 3.2% of cancer drug development
research comes from indirect sources in the USA, compared to 44.7% for Europe). Hence,
taking additional indirect investment into account, Europe as a whole considerably closes
the gap with USA public sector funding of cancer drug development (i.e. 0.011% of
European GDP goes into cancer drug development compared to 0.018% of the USA GDP).
Furthermore, a great deal of cancer research relies on charitable organizations’ support
in Europe. Indeed, direct non-commercial spend is almost equally shared between
governmental (€298.7 million) and philanthropic (€301 million) organisations. In contrast, in
the USA only 13.76% of non-commercial cancer research comes directly from charitable
funders.
s
EROCAN+Plus has the objective to support the harmonization of European cancer research and EUSTIR to
integrate research and to develop a common European strategy on breast cancer.
See: www.eurocanplus.org
88
For some EU countries (e.g. Sweden and Hungary) the fact that this balance does not
exist and charitable funding is dominating reveals the different philanthropy patterns that
exist among countries.60 Charitable fundraising relies on altruism, often associated with
uncertainty, but is quite significant in some cases and is an additional source to
governmental and industry funding.61 Ideally, there could be a closer collaboration and
coordination between governmental and charitable funders. Although a politically
challenging goal62, steps towards establishing this funding model have already been
established both in the USA and in Europe with the founding of ‘umbrella’ organisations
such as the C-Changet (USA), the NCRI (UK) and INCa (France).u
As the strategies of the charitable organisations were beyond the scope of this review,
the possibility that several fundraising organisations supporting cancer care delivery may
not have been taken into account exists. Moreover, EU Commission funding was not
included in the calculations of cancer research spending for Europe as a whole neither in
absolute terms, nor per capita, nor as a percentage of GDP. Therefore, it is likely that the
gap between Europe and USA is overestimated.
[IV] CSO coding system: National strategic planning with international context
In order to ensure progress in cancer research, international cooperation is essential.
Recognizing that, in September 2000, several international cancer funding organizations
decided to use a common scientific outline, known as the Common Scientific Outline (CSO),
to code their research portfolios. The Initial Cancer Research (ICR) Partners, formerly known
as the CSO Partners, were US and UK organisations such as the US NCI and Cancer Research
t
See: http://www.c-changetogether.org/
u
L’ Institut National du Cancer. See: http://www.e-cancer.fr/
89
UK. In 2007, the Canadian Cancer Research Alliance (CCRA) which represents key
government and non-governmental cancer funding organizations joined the ICR Partners.v
The CSO makes it possible to compare and contrast the research portfolios of multiple
organizations, and provides the information needed to improve coordination among
research organizations. To facilitate information sharing between ICR Partners, the
International Cancer Research Portfolio (ICRP), an information database on ongoing cancer
research funded by the ICR Partners was created. The ICRP public website can provide
contacts for multidisciplinary research and partnerships between researchers conducting
similar work, in addition to inform internal and joint policies of cancer funding organizations
and government/policy officials and to set directions for future research efforts.
3.4.2. Private sector funding
Private (i.e. commercial) sector cancer research funders, which are represented by the
pharmaceutical and the biotechnology industries, are estimated to invest around €6 billion
annually worldwide63, an amount that accounts for one quarter of total global research
expenditure and that is mainly invested in the USA and Europe.64
Pharmaceutical companies seem to account for the great majority of total private
expenditure. Indeed, the research budget of the pharmaceutical firms has increased steeply
(approximately by 13% annually) since 1970.65 Furthermore, it has been estimated in
previous studies, using 2004 data, that 7% to 12% of the total industry R&D expenditure is
dedicated to cancer research.7, 50 Taking into account that oncology drug sales account for
5% of total drug sales and that 15% of total cancer drug sales are reinvested in R&D
compared to 10% of global drug sales, the increasing interest of pharmaceutical
manufacturers to invest in oncology is further reflected.19
v
See: http://www.cancerportfolio.org/faq.jsp#cso_partners
90
Despite the increase of R&D expenditures across the industry, the amount of New Drug
Applications (NDAs) has stayed flat during the 30 last years, reflecting an almost tenfold
drop in R&D productivity.51,53 The recent overall drop in the number of New Chemical
Entities (NCEs) approved by the US Food and Drug Administration (FDA) each year is a key
challenge for the pharmaceutical industry.7 Given also that many patents are about to
expire, the problem becomes bigger, as many firms do not have adequate effective new
medicines to balance this loss.56
Traditionally, large pharmaceutical manufacturers used to conduct in-house discovery
research, designed their own clinical trials, manufactured their own drugs and were in
charge for their sales and distribution channels.66 In response to the challenges discussed
above, the industry has recently experienced a major transformation. A growing number of
new drugs derive from in-licensing rather than in-house research. For instance in 2002, 40%
of the big pharmaceutical companies’ pipelines originated from in-licensed resources, in
contrast to merely sixteen percent in 1980.67 This highlights the changing dynamics in R&D
and, probably, also underscores the need for a different R&D model that makes better use
of technological advances from a wider pool of knowledge.
The fact that increasingly big pharmaceutical companies invest in other start-up
biomedical/biotechnology companies is also an interesting trend (e.g. the Novartis Venture
Fund was launched in 1996 and Lilly Ventures in 2001).68 The finding that key venture
investment prospects keep emerging when the vertically integrated pharmaceutical industry
is considered from the perspective of the potential of developing large horizontal players,
can explain this trend.57
Comparing Europe’s private sector to USA’s, it seems that when the geographical origin
of industry’s publications is taken into account, the cancer research activity between the
two areas is balanced. Indeed, Europe accounted for 45.9% of total pharmaceutical cancer
research spend in 2004, despite the established opinion that Europe is weaker in attracting
industry research funds.51
Finally, it must be noted that the significant contribution of the private sector may be
underestimated in this review due to the lack of direct industry data on cancer research
spend and our approximation through bibliometric exercises. In addition, data were limited
to major pharmaceutical companies, and despite the fact that they account for the
91
overwhelming majority of private funding, the contribution of small and medium firms as
well as biotechnology companies was not taken into account.
92
3.4.3. PPPs in cancer drug development
Modern drug discovery has become the product of collaboration. Many sectors
contribute, particularly in building the basic science foundations, as both public and private
organizations play unique but increasingly interdependent roles in translating basic research
into medicine (Box 3.9).
[I] Industry and academia collaboration against cancer
Increasingly research policy has been directed to supporting the transfer of technology
from knowledge generating organisations in the public sector (e.g. universities) to firms
through the establishment of co-operative links. Rather than feeling challenged, the
industry welcomes academic contribution in identifying and validating early drug targets, as
this can lead to reduction of corporate risk and to a smoother drug development
operational process. The potential of closer collaboration among universities, biotechnology
and pharmaceutical companies, could lead to universities conducting basic research,
biotechnology firms developing technology and chemistry, while pharmaceutical firms
would be in charge of developing clinical trials. Hence, it is not surprising that discovery
centres have been established close to major academic research hubs. For instance,
Novartis and Merck funded in 2002 drug discovery centers in Boston USA, not far from the
Harvard and MIT universities.,69, 70
[II] Integration of public and private investment
As a result of the high socio-political priority given to health by countries such as the
USA, the UK and Sweden, total research and development budgets are increasing while
emphasizing cost-effective innovations. At the same time, the industry is more and more
utilizing research funded directly from public sources and cooperating with public research
institutions.71
Over half of the significant cancer research activity conducted both in the USA and in
Europe is the product of partnerships with the public sector, a trend that has been
increasing.53 In fact, recently, the majority of cancer research funding policies have
accentuated the public-private partnership path. However, as EU funds are often being
joined with industry, there are concerns that “if all increases in EU cancer research funding
go this way Europe’s intrinsic creativity would be distorted by encouraging subsidy-seeking
93
behavior and essential areas of public health relevant to cancer, but not amenable to a
business approach would remain orphans”.53
Box 3.9
Cancer research through Public-Private Collaboration in the USA
Big biopharmaceutical companies are the principal source of R&D funding for
innovative drugs, both for projects in their own laboratories as well as for research
licensed from other sectors.
Smaller companies also drive innovation, conducting basic research, drug discovery,
preclinical experiments and, in some cases, clinical trials.
The National Institutes of Health (NIH) provides leadership and funding support to
universities, medical schools, research centers and other nonprofit institutions, and
stimulates basic research and early stage development of technologies that enable
further targeted drug discovery and development.
The National Cancer Institute (NCI) often seeks Cooperative Research and
Development Agreements (CRADAs) with pharmaceutical or biotechnology
companies. The goals of the CRADAs commonly include the rapid publication of
research results and timely commercialization of products, diagnostics and
treatments resulting from the research. The CRADA Collaborators usually have the
option to negotiate the terms of an exclusive or nonexclusive commercialization
license to subject inventions arising under the CRADAs.
Sources: Drug Discovery and Development: Understanding the R&D Process, PhRMA Brochure, February 2007
Cooperative Research and Development Agreements (CRADAs): http://www.usbr.gov/research/techtransfer/together/crada/whatcrada.html
94
3.5. Concluding remarks
Cancer drug research and development is a multifaceted activity that seeks to relieve the
burden of more than 15 million people estimated to face the disease by 2020. It comprises
not only the discovery and development of new drugs but also in the enhancement of
current therapies, the improvement patient quality of life and the prevention of the disease.
As research activity and high-quality health care delivery are linked, intensive research
and drug development is likely to have a positive effect on the overall care, and therefore,
the quality of life of cancer patients. Triggering cancer research funding and creating the
necessary infrastructure to conduct research can also make a country more attractive to
research and contribute to the prevention and likely reversal of “brain drain”.
This survey identified 174 major public funding sources across Europe and USA, which
were estimated to have invested €8.6 billion in cancer research in 2007. Adding in the
private sector contributions, that are estimated to be in the region of €6 billion, it becomes
clear that significant amounts are spent on cancer research. Still, the private sector’s
contribution is both an approximation and an underestimate as important components
could not be included due to lack of data.
While the contribution of the nonprofit philanthropic sector is growing, some EU
Member States still fail to provide adequate governmental funding. This is of some concern
in the case of countries that can afford higher levels of cancer research funding and that
have the required research workforce.
Public-private partnerships are also strong and growing in both Europe and the USA, and
public funders should recognize and support these joint efforts, given the increasing
complexity and quantity of the oncology drug pipeline.
However, difficult policy decisions need to be made on what research will be funded
given the need to prioritize and optimize resources.
Despite the likelihood of any omissions and over- or under-estimations, this section has
mapped the diverse funding sources of cancer R&D and underlined that bureaucracy is
often a major threat to this complex, multifaceted, but important effort. In the face of the
95
steps that have been taken recently in promoting cancer research, more countries need to
recognize cancer prevention as a high national priority and to engage in international
collaboration and coordination strategies.
96
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100
4. RESEARCH ACTIVITY IN DRUG DEVELOPMENT:
A BIBLIOMETRIC ANALYSIS
4.1. Background and Objectives
Traditionally policy analysis of cancer drug discovery and development have
relied on qualitative interview-based methodologies and quantitative data gathered
from sales. The use of bibliometrics is a novel way to gather objective intelligence on
research domains and the funding of these domains.1
Research into the causes, prevention, diagnosis and treatment of cancer is a US$
17 billion global enterprise, encompassing basic research on genetics and cell
science, epidemiology, diagnostic tools and procedures, as well as the three main
treatment paths of surgery, chemotherapy and radiotherapy. Each year, about
40,000 papers relevant to cancer research are published in scientific journals.
providing a rich source of intelligence on who, what and where particular domains
and types of research in cancer are being conducted.2 Publications of research
findings can be used as a proxy indicator, enabling examination of geographical
distribution of cancer research activity, its characteristics (which manifestations of
cancer? which approaches to tackling the disease? patient- or laboratory-based?),
and whether these correlate with the burden of disease. Transnational comparisons
may reveal that particular countries are under-researching cancer or certain aspects
of the disease.
The funding of research is not always top-down, as driven by clear policy from
government in response to a perceived need, but may also be bottom-up, especially
where research projects are proposed by investigators and then selected for funding
after a peer-review process. The motivation here may be intellectual, or it can be the
personal experience of individual researchers whose family members or friends may
have succumbed to a particular manifestation of the disease. Current methodologies
to estimate research expenditure do not, as a rule take into acount the complexity of
101
funding sources and so given figures are often nothing more than guess-estimates.
The use of bibliometrics provides an objective method for describing the funders of
cancer research.
That cancer research covers such a huge range of scientific
endeavour, from the social to natural sciences, makes the task of developing realistic
measures of the state and funding of global cancer research complex.3 In this
chapter we provide the first application of bibliometrics to the study of cancer drug
development.
The broad objectives of this chapter are as follows:
1. To study the trends in global cancer durg discovery and development,
including a focus on 19 specific anti-cancer drugs choosen as a surrogate subset to cover specific time periods, types of anti-cancer drugs (new chemical
entities and biologcals) and sources.
2. To understand the relationship(s) between research activity and site specific
DALY’s; are specific areas being under (or over) represented?
3. To review the trends in drug development research in terms of their research
level, geography (who, where) and funding mix.
With regards to the first objective, apart from early phase clinical trials where we
know publications (outputs) do not reflect activity, bibliometrics provides an
objective window on the current and past state of cancer drug development. With
access to the major databases we are able, using algorithms developed with key drug
names, to analyse the trends in output and impact by country, institution and even
researcher. We can look at how models of partnership (institution-to-institution and
institution-industry) have changed and also at the patterns of funders over time.
Such changes can then be reviewed in the context of the impact of national policies.
This objective will focus on those cancer drugs with an MA, and depending on
complexity may also sample a cross-section of those NME’s that failed to make it to
market.
With regards to the second and third objectives, the question of how and who
funds cancer drug development can most effectively be answered by looking at the
cumulative lifetime from incept (NME) to clinic. We know that this R&D lifetime is a
complex interplay between many different countries, funders and people. Taking a
102
representative sample of current cancer drugs, we will look at their funding histories
from inception to market.
4.2. Methods
4.2.1. Focus of study
This study focused on a set of anti-cancer drugs comprised of 19 new molecular
entities, together with trigraph codes used in this chapter to designate them in the
tables and figures (Table 4.1). These drugs were chosen, using statistical methods, as
a representative group for drug development as a whole to cover new chemical
entities (including endocrine therapies) and biologicals as well as to cover three
distinct periods of cancer drug research.
The main information gathered was:
•
the numbers of papers from 1963 to 2009 for each of the 19 drugs published
in the Web of Science (WoS);
•
their research levels (on a scale from clinical to basic);
•
their geographical origins (USA, Europe, Rest of the World);
•
the cancer site(s).eg., breast, lung, for which the drug was being investigated;
•
the funding sources for the papers.
Data was also obtained on the total numbers of cancer research papers from
1984-2008 and on the numbers of such papers concerned with named drugs from a
list of 150 (including pre-clinical designations) (Table 4.2).
103
Table 4.1
Major 19 selected cancer drugs used for data collection
Code
ALE
ANA
BEV
BOR
CAP
CAR
CET
Drug
alemtuzumab
anastrozole
bevacizumab
bortezomib
capecitabine
carboplatin
cetuximab
Trade name
Campath
Arimidex
Avastin
Velcade
Xeloda
Paraplatin
Erbitux
CIS
DOC
EXE
GEF
IRI
LAP
cisplatin
docetaxel
exemestane
gefitinib
irinotecan
lapatinib
Platinol
Taxotere
Aromasin
Iressa
Camptosar
Tykerb
SUN
TAM
TEM
sunitinib
tamoxifen
temozolomide
Sutent
Nolvadex
Temodar
TRA
VBL
VCR
trastuzumab
vinblastine
vincristine
Herceptin
Velban
Oncovin
Source: The authors.
104
Code names
10864/715969/MoAb CD52
ICI-D1033/ZD-1033
rhuMA bVEGF/Anti VEGF
LDP 341/MLN341/PS-341
Ro 09-1978-000
JM-8
Chimeric MoAB C225/MOAB
C225
SP-4-2
RP 56976
FCE-24304
ZD 1839
CPT-11/U-101440E
GSK572016/GW2016/GW572016
SU011248/SU11248
ICI 46474
CCRG-81045/M&B 39831
RP-46161/SCH 52365
MOAB HER2/rhuMAb HER2
VLB
VCR
MA
2001
2002
2006
2006
1998
1989
2004
1978
1996
2005
2003
1996
2007
2007
1986
1999
2006
1965
1963
Table 4.2
List of all drugs listed as being approved for cancer treatment (2009)
5-fu
6-mp
6-tg
abarelix
actinomycin d
aldesleukin
aldesleukin
alemtuzumab
alitretinoin
allopurinol
altretamine
amifostine
anakinra
anastrozole
arsenic trioxide
asparaginase
atra
azacitidine
bcg live
bevacizumab
bexarotene
bleomycin
bortezomib
busulfan
calusterone
capecitabine
carboplatin
carmustine
ccnu
celecoxib
cetuximab
chlorambucil
cisplatin
cladribine
clofarabine
cyclophosphamide
cytarabine
dacarbazine
interferon alfa-2b
Iressa
irinotecan
lapatinib ditosylate
lenalidomide
letrozole
leucovorin
leuprolide
levamisole
lomustine
l-pam
meclorethamine
megestrol
melphalan
mercaptopurine
mesna
methotrexate
methoxsalen
mithramycin
mitomycin c
mitotane
mitoxantrone
nandrolone
phenpropionate
nelarabine
nitrogen mustard
nofetumomab
oprelvekin
oxaliplatin
paclitaxel
palifermin
pamidronate
panitumumab
pegademase
pegaspargase
pegfilgrastim
peginterferon alfa-2b
pemetrexed
disodium
dactinomycin
dalteparin
darbepoetin alfa
dasatinib
daunomycin
daunorubicin
decitabine
denileukin
diftitox
dexrazoxane
docetaxel
doxorubicin
dromostanolone
propionate
eculizumab
elliott's b solution
epirubicin
epoetin alfa
erlotinib
estramustine
etoposide
exemestane
fentanyl citrate
filgrastim
floxuridine
fludarabine
fluorouracil
fulvestrant
gefitinib
gemcitabine
gemtuzumab ozogamicin
goserelin
histrelin
hydroxyurea
ibritumomab
idarubicin
ifosfamide
imatinib mesylate
interferon alfa-2a
Pentostatin
Pipobroman
Plicamycin
porfimer sodium
Procarbazine
Quinacrine
Rasburicase
Rituximab
Sargramostim
Sorafenib
Streptozocin
Sunitinib
Talc
Tamoxifen
Temozolomide
Teniposide
Testolactone
Thalidomide
Thioguanine
Thiotepa
Tiuxetan
Topotecan
Toremifene
Tositumomab
Trastuzumab
Tretinoin
uracil mustard
Valrubicin
Vinblastine
Vincristine
Vinorelbine
vm-26
Vorinostat
vp-16
Zoledronate
zoledronic acid
Source: The authors.
4.2.2. Selection of papers
Articles, notes until 1996 and reviews were identified from the WoS from 1963 to
mid-2009 using search statements looking for the selected drugs (Table 4.1)
105
appearing in the paper title. Bibliographic details (authors, title, document type,
language, source, addresses) of all such papers were downloaded to an MS Excel
spreadsheet.
Subsequently, titles were filtered to allow all papers involving each of the 19
drugs to be marked with a “1” in a separate column of the spreadsheet. The
numbers of papers ranged from 10,299 for cisplatin (CIS) to 83 for lapitinib (LAP);
early years (from 1963) contained only papers concerning vinblastine (VBL) and
vincristine (VCR), whereas papers on sunitinib (SUN) appeared only from 2003. For
drugs with longer histories, the papers were divided into five quintiles based on
publication years, but the quintile sizes varied covering different numbers of years.23
Next, papers were examined for funding acknowledgements. The intention was
to select reasonable size samples permiting a valid analysis for each drug and to
uniformly cover the time frame in which papers appeared. Due to large variations in
paper numbers per drug, more than two orders of magnitude, it was decided to
make the sample sizes proportional to the cube roots of the paper numbers, then to
make a selection of an equal number of randomly chosen papers per year if available
(although in early years, very often all the papers were needed for the sample). The
sample sizes varied from 360 for CIS to 72 for LAP, and the number of papers per
year varied from 21 for bevacuzimab (BEV) to 4 for exemestane (EXE) and VBL.
4.2.3. Comparison with outputs of all cancer research and all drugs
The WoS was searched separately to determine the numbers of cancer research
papers each year from 1994-2008 (15 years) by means of a filter, labelled ONCOL,
consisting of two parts: a list of specialist cancer journals (e.g. British Journal of
Cancer, Cancer, Leukemia) and a list of cancer title words (e.g., adenoma*24, BRCA1,
carcino*, daunorubicin, EBV), and papers were selected if they were in one of the
specialist journals, or contained one of the list of title words, or both. The filter was
developed by Dr Lynne Davies of Cancer Research UK, and recently updated to
23
For four of the drugs, this was not possible, and only four “quintiles” could be used.
24
The * denotes all terms linked to the primary word/term.
106
include new drugs used only for cancer as well as genes pre-disposing to cancer. Its
specificity (precision) and sensitivity (recall) were both close to 0.95. A subset of
these papers was also identified having as a title word one of a list of 150 drugs used
for cancer treatment (Table 4.2) – some are also used for other indications. There
were 46,796 papers and analysed by year, by country (leading 15 countries whose
papers were in the original set, Table 4.3) and also by cancer manifestation (site)
(leading 16 listed by WHO in its burden of disease statistics (Table 4.4)).
Cancer represents over 16% of the estimated overall disease burden measured in
Disability Adjusted Life Years (DALYs) in the 12 developed industrialised countries
(Table 4.3) (excluding China, India and South Korea), but accounts for 5% of the
world disease burden (Table 4.4). Lung cancer has the highest cancer burden in both
DALYs and deaths, followed at some distance by stomach, liver, colorectal and breast
cancer, although the latter receives much more publicity than the others.4
Table 4.3
Estimated total disease burden (DALYs) and cancer burden (DALYs, %)
in 15 countries (2004)
Code
Country
AU
CA
CN
DE
ES
FR
GR
IN
IT
JP
KR
NL
SE
UK
US
Australia
Canada
China
Germany
Spain
France
Greece
India
Italy
Japan
South Korea
The Netherlands
Sweden
United Kingdom
United States
All DALYs
(1,000)
2223
3685
200524
10358
4858
7434
1310
305112
6575
12997
6165
1868
1033
7718
41372
Source: The authors.
107
Cancer DALYs
(1,000s)
332
584
19302
1747
809
1355
210
8487
1202
2406
785
343
151
1204
5085
Cancer DALYs
(%)
14.9
15.8
9.6
16.9
16.6
18.2
16.0
2.8
18.3
18.5
12.7
18.4
14.6
15.6
12.3
Table 4.4
Main 16 cancer sites, disease burdens (DALYs) and mortality rates
(2004)
Code
Cancer Site
BLA
CER
COL
LEU
LIV
LUN
Bladder
Cervix
Colon and rectum
Leukaemia
Liver
Trachea, bronchus,
lung
Lymphomas, myeloma
Breast
Melanoma, other skin
Mouth and oropharynx
Oesophagus
Ovary
Pancreas
Prostate
Stomach
Uterus
LYM
MAM
MEL
MOU
OES
OVA
PAN
PRO
STO
UTE
DALYs
(000s)
1449
3715
5863
4935
6705
11753
DALYs
(% total)
1.9
4.8
7.5
6.4
8.6
15.1
Mortality
(000s)
187
268
638
276
609
1322
Mortality
(% total)
2.5
3.6
8.6
3.7
8.2
17.8
4275
6620
705
3785
4765
1742
2216
1843
7484
742
5.5
8.5
0.9
4.9
6.1
2.2
2.9
2.4
9.6
1.0
332
518
68
335
508
144
265
307
802
55
4.5
7.0
0.9
4.5
6.9
1.9
3.6
4.1
10.8
0.7
Source: WHO, 2008.
The 15 leading countries vary in degree of overall cancer burden (Table 4.3). The
proportion of world mean values for each country is cross-matrixed (Table 4.3, DALY
%) with the proportion of each cancer site (Table 4.4, % DALYs) (Table 4.5).
Particularly high values are tinted pink and gray while or particularly low values are
tinted bright or light green. Some cancer types are relatively uncommon in high
income countries, such as cervical, leukaemia, liver, mouth/head and neck,
oesophageal and stomach cancer (except in the Far East); others are more common
such as bladder, colorectal, melanoma (especially in Australia), pancreatic, prostate
and uterine cancer. Breast and lung cancer are a major burden everywhere, lung
cancer especially in north America and Greece, although breast cancer is low in
Korea and China.
108
Table 4.5
Ratios of relative disease burden (DALYs) for 16 cancer sites to global average in 15 countries
AU
CA
CN
DE
ES
FR
GR
IN
IT
JP
KR
NL
SE
UK
US
BLA
1.1
1.4
0.5
1.2
2.2
1.6
1.9
0.8
1.6
0.8
0.5
1.3
1.5
1.5
1.4
CER
0.3
0.4
0.3
0.4
0.3
0.3
0.3
2.4
0.2
0.4
0.4
0.2
0.3
0.4
0.5
COL
1.7
1.5
0.7
1.7
1.8
1.5
1.2
0.6
1.5
1.9
1.2
1.6
1.6
1.5
1.4
LEU
0.7
0.6
1.0
0.6
0.6
0.6
0.8
1.5
0.6
0.5
0.6
0.5
0.6
0.5
0.7
LIV
0.3
0.2
2.2
0.3
0.4
0.5
0.6
0.2
0.7
1.2
2.3
0.2
0.3
0.2
0.3
LUN
1.0
1.5
1.2
1.3
1.3
1.3
1.5
0.5
1.3
1.0
1.1
1.5
1.0
1.3
1.6
LYM
1.1
1.1
0.4
0.8
0.9
0.9
0.7
1.3
0.9
0.7
0.6
0.9
1.0
1.0
1.0
MAM
1.5
1.4
0.6
1.3
1.0
1.3
1.3
0.9
1.2
0.8
0.4
1.5
1.2
1.4
1.4
MEL
5.0
2.1
0.1
1.8
1.6
2.0
1.6
0.3
1.9
0.4
0.5
2.8
3.0
2.2
2.6
MOU
0.4
0.4
0.5
0.7
0.7
1.0
0.3
2.9
0.5
0.4
0.3
0.4
0.3
0.4
0.3
OES
0.5
0.4
2.0
0.4
0.4
0.6
0.1
1.4
0.2
0.6
0.3
0.6
0.3
0.8
0.4
OVA
1.1
1.2
0.4
1.2
0.9
1.0
1.0
1.3
1.0
1.0
0.6
1.2
1.7
1.5
1.3
PAN
1.4
1.5
0.8
1.9
1.5
1.5
1.5
0.6
1.7
2.2
1.5
1.5
2.1
1.4
1.6
PRO
2.9
2.0
0.1
1.8
1.7
1.8
1.8
0.6
1.4
0.9
0.4
1.8
3.2
2.2
1.9
STO
0.3
0.3
1.9
0.5
0.6
0.3
0.6
0.6
0.6
1.5
1.8
0.4
0.4
0.4
0.2
UTE
1.5
1.4
0.3
1.2
1.5
2.0
1.6
0.4
1.7
1.5
0.4
1.6
2.1
1.5
1.6
Notes: Values over 2.0 coloured pink; values over 1.41 in light gray; values below 0.71 in light green; values below 0.5 in bright green.
109
4.2.4. Research Levels
For each year, the ratio of papers outputs of the major 19 selected drugs was
compared with total oncology research and total cancer drug-related papers. The
latter tally was broken down by country and by cancer site to provide information on
how cancer drug research overall is conducted. This was determined in two ways: by
analysis of the actual titles of the papers, and by an analysis of the titles of all the
papers published in the same journal for the relevant period. The procedure has
been described earlier,2 based on the presence of over 100 “clinical” and over 100
“basic” words in the titles of papers. Examples include clinical words (abdominal,
breast, child, depression, elderly) and basic words (apoptosis, binding, channel, DNA,
embryos, folding, gene).
Groups of papers were allocated a mean research level on a scale from 1 =
clinical observation to 4 = basic research, both on the basis of their titles (RL p) and
their journals (RL j). Comparison of these two mean values showed whether the
papers were published in more clinical or more basic journals. The determination of
values of RL p and RL j for the different quintiles for each drug also allowed time
variations to be seen. [For the ensemble of papers, the tendency was for them to
become more clinical, but this was not so for all drugs.]
An additional indicator of research type was information on whether the paper
was a report of a clinical trial, and if so, whether Phase I, Phase II or Phase III. This
was obtained from the paper titles. Although most used Roman numerals, a few
used Arabic numerals instead to indicate the phase number; also some papers
described Phase I/II or II/III trials and thus allocated to both groups.
4.2.5. Geographical Analysis
A special macro allowed for an analysis of the addresses on the papers, and for
each country’s contribution to be determined on a fractional count basis.25
For
some of the analysis, countries were divided into three groups: the USA, Europe
25
A paper with two UK and one French address would count unity for each on an integer count
basis and 0.67 and 0.33 respectively on a fractional count basis.
110
(consisting of the EU27 Member States, plus Iceland, Norway, Switzerland) (EUR30),
and the Rest of the World (RoW) dominated mainly by Japan, but also included
Canada, South Korea, China, Australia and India. The contribution of the latter group
normally increased over the five quintiles, but not always. For each of the 19
selected drugs, the geographical percentage distribution of papers in the five
quintiles was determined, although for drugs with rather few papers these values
often moved erratically.
In addition, the contribution of each of the 15 selected countries was determined
for the whole set of papers and also for the individual drugs.
International
collaboration between the selected countries was calculated and presented as each
country’s preference (or lack of it) for each other country, based on that country’s
percentage presence in the set of papers.
4.2.6. Cancer Manifestations and Disease Burden
The papers for the 19 selected cancer drugs was filtered to identify those papers
concerned with one (or more) of the main 16 cancer sites (Table 4.4). For each
cancer site, a set of title words and journal name strings was developed by Professor
Sullivan, and applied to the file by means of another special macro written by Philip
Roe. This listed in a single column the manifestation(s) investigated in each paper;
about half the papers did not mention any of them. Each of these sub-filters was
also prepared in the format used in the WoS, and used to determine how many of all
the drug-related cancer papers were directed to each cancer site, year by year. This
allowed time trends to be seen after normalization for the overall numbers of cancer
research papers.
Comparisons were also made between the amount of research effort on all
cancer drugs, on the 19 selected cancer drugs, and on the world-wide burden of
disease of the 16 cancer sites. Some cancer sites appeared under-researched in
relation to their burden, however, this may mean that other treatments were used
(surgery and radiotherapy) including adjuvant.
4.2.7. Funding of Cancer Drug Research
111
Funding of papers for each 19 drugs was also determined for a sample of papers.
The methodology for this process has been established for many years, and found
that the number of such financial acknowledgements plays a major role in
determining whether the papers will be published in high impact journals, in turn
receiving many citations.5, 6
Acknowledgements were recorded as three codes: first, a trigraph denoting the
individual funding body (e.g., MRC = UK Medical Research Council; CUK = Cancer
Research UK); second, a digraph denoting the category (government, private-nonprofit, industry, international, and sub-categories of each of these); and third, the
ISO digraph denoting the country (EU for the European Union, XN for international
bodies). Previous funding analyses to date have been for papers from individual
countries with distinctions made between country funding from government or
charities and that from abroad. In this study, the focus was on individual drugs and
their development over time so this distinction was dropped, and the analysis
focussed simply on whether the funding sources were governmental, private-nonprofit, commercial or international – or none. The latter is not uncommon in medical
research, particularly for clinical work; in Europe such papers would normally be
funded indirectly by the state either through the higher education or the hospital
system. We also investigated the extent to which pharmaceutical and biotech
companies other than that associated with the initial marketing of a drug were
involved in supporting both early and later research.
In addition to recording all funding for a sample of the papers, addresses of all
papers were searched for the presence of the company responsible for first
marketing of each of the 19 drugs using company names, trigraph codes and search
strings (Table 4.6). Twenty six pharmaceutical manufacturers were identified in this
way, twelve of which were responsible for developing the 19 drugs under
investigation. A sub-set of papers from the year of marketing approval and previous
years for each drug was separately analysed to test the hypothesis that the company
developing the drug would be the only one supporting such research intra-murally
during that time.
Table 4.6
112
Pharmaceutical companies involved in 19 cancer drugs: trigraph
identifying codes, search strings and drug codes
Code
Company
ISO
Search strings
Drugs
developed
BMS
GNH
HLR
IKL
LLL
MLF
PFZ
PUJ
SCH
SKB
VAZ
ZAT
Bristol Myers Squibb
Genentech
Hoffmann La Roche
Imclone Systems
Eli Lilly
Millennium
Pfizer
Pharmacia Upjohn
Schering Plough
SmithKline Beecham
Aventis Pharma
AstraZeneca
US
US
CH
US
US
US
US
US
US
UK
FR
UK
BRISTOL-MYERS, SQUIBB
GENENTECH-INC
ROCHE-, LA-ROCHE
IMCLONE-SYST
LILLY
MILLENNIUM-PHARM, ILEX
PFIZER
PHARMACIA, UPJOHN
PLOUGH
SMITHKLINE, BEECHAM
AVENTIS, HOECHST, RHONE-P
ASTRA, ZENECA
CAR, CIS
BEV, TRA
CAP
CET
VBL, VCR
ALE, BOR
SUN
EXE, IRI
TEM
LAP
DOC
ANA, GEF,
TAM
ABB
AMN
BGN
BOI
DII
EIS
EMD
GLX
JJJ
MRK
NVP
SIG
TAK
WYH
Abbott Laboratories
Amgen
Biogen
Böhringer Ingelheim
Daiichi Sankyo
Eisai
Merck KgaA
Glaxo Wellcome
Johnson & Johnson
Merck & Co
Novartis
Schering AG
Takeda
Wyeth
US
US
US
DE
JP
JP
DE
UK
US
US
CH
DE
JP
US
ABBOTT
AMGEN
BIOGEN-, IDEC
INGELHEIM
DAIICHI-, SANKYOEISAIMERCK-KGAA, SERONO
GLAXO not SMITHKLINE
JOHNSON-&-JOHNSON, JANSSEN, CILAG
MERCK not (MERCK-KGAA or SERONO)
NOVARTIS, CHIRON, CIBA, SANDOZ
BAYER, SCHERING-AG
TAKEDA
WYETH, LEDERLE
113
4.3. Results
4.3.1. Volume of cancer drug paper outputs
The number of papers for the 19 selected drugs increased rapidly over time, both
because of the general rise in drug-related research and because new drugs have
been successively added to the portfolio (Figure 4.1). The proportion of the 19 drugs
in total cancer research and has remained relatively stable with a slight upward
trend (Figure 4.2).
Figure 4.1
Total WoS output for 19 cancer drug research papers (3-year running
means) (1970- 2007)
2500
Paper s per year
2000
1500
1000
500
0
1970
1980
Year
114
1990
2000
Figure 4.2
Proportion of total drug (blue) and 19 drugs (red) cancer research papers
of total cancer research papers
Percent of all cancer papers
10
All drugs in cancer
8
19 selected drugs
6
4
2
0
1994
1996
1998
2000
2002
2004
2006
2008
Papers on the 19 selected drugs increased from an average of 2.7% of all
oncology in 1994-98 to 3.6% in 2004-08, whereas overall drug papers have only
increased from 6.9% to 7.8% over the same period. The numbers of papers per 19
drugs are presented on a logarithmis scale (some double counting occured: the sum
of individual totals is 30,635, 5.4% more than the total number of papers in the file)
(Figure 4.3).
Figure 4.3
WoS cancer drug papers for 19 cancer drugs (1963-2009)
T otal papers (log scale)
10000
1000
100
10
CIS TAM CAR VCR DOC VBL
IRI
BEV
GEF CAP TEM TRA BOR ALE
115
CET SUN ANA EXE LAP
The overall distribution of papers for the 15 nations, per integer and
fractional count bases, found integer counts exceeding fractional counts due to
international collaboration – particularly high for Australia and Sweden, but rather
low for Japan, Korea, Greece and India (Figure 4.4). Language of the papers is
predominantly English, with major European languages decreasing over time
(Table 4.7).
Figure 4.4
Distribution of papers in 15 countries (integer, fractional counts)
Papers in the 19-drug file
10000
INT
FRAC
1000
100
US
JP
IT
UK
DE
FR
NL
CA
ES
KR
GR
CN
AU
SE
IN
Table 4.7
Publication languages in cancer drug research papers (1963-2009)
Years
Total
English
196379
1098
1003
German
%
91.3
198089
3907
3678
38
3.46
French
33
Russian
%
94.1
199099
8453
8260
89
2.28
3.01
79
3
0.27
Italian
13
Spanish
97.7
200009
15294
15030
98.3
65
0.77
104
0.68
2.02
85
1.01
84
0.55
31
0.79
23
0.27
10
0.07
1.18
3
0.08
5
0.06
9
0.06
4
0.36
14
0.36
5
0.06
13
0.09
Japanese
1
0.09
4
0.10
7
0.08
7
0.05
Chinese
0
0.00
4
0.10
1
0.01
12
0.08
Others
3
0.27
5
0.13
2
0.02
25
0.16
116
%
%
4.3.2. National involvement in cancer drug research
[I] International collaboration
It is possible to determine how much the different countries value research
participation in relation to their international collaboration in total, best calculated
on a fractional count basis (Table 4.8). This is not symmetrical on a fractional count
basis, although it would be if calculated on an integer count basis.
For example, Canada contributed 104 papers to the US integer count of 10,430,
whereas the US contributed 163 papers to the Canadian integer count of 1,090, with
309 papers with both Canadian and US authors. Since Canada’s fractional count
contribution to the total paper set was 2.77%, or 4.13% if the US presence
accounting for 32.9% was neglected, thus contributing 0.0413 x the foreign
contribution to US papers (10430 – 9452 = 978), or 40 papers. Its actual contribution
was almost 2.6 times this estimate, showing that Canadian scientists are very much
preferred international partners for US researchers, statistically highly significant.
The situation for Japan is the reverse, with only 86 contributions to US output
compared with an expectation, on the basis of its percentage presence in the world
less the USA, of 154 papers. On the other hand, Chinese scientists are somewhat
over-selected (by x 1.2) by US researchers, showing that its policy of openness has
achieved results.
The matrix of values of observed to expected contributions shows that
international collaboration is still firmly based on geographical proximity, linguistic
and cultural ties, though intra-European collaboration is of major significance (Table
4.9). Thus Canada and the USA favour each other, although the USA also has good
links with Japanese and Indian scientists. Three far Eastern countries (China, Japan
and Korea) all give above-average preference to each other, and Korea (but not
others) to India.
Within Europe, the Netherlands and the UK appear to play
important roles in collaboration, and there are strong reciprocal links between the
UK and Australia. Perhaps surprisingly, India prefers Germany to the UK among
European countries (this has been observed in other fields), but its preferred partner
is Australia.
117
118
Table 4.8
Matrix of total cancer research papers per country to the 19 selected cancer drug papers per country (fractional counts)
Number of the selected 19 cancer drug papers
per Country
US
US
JP
IT
UK
DE
FR
NL
CA
ES
KR
GR
CN
AU
SE
IN
87
82
136
85
78
57
163
41
16
12
32
37
20
13
JP
86
1.7
9.4
5.9
6.5
4.6
6.0
2.4
7.9
0
13
2.4
1.3
0.5
IT
84
1.6
43
15
26
17
12
15
0.1
3.3
4.0
4.8
4.7
0.2
UK
122
9.5
36
38
43
39
24
18
0.7
8.9
6.2
32
13
1.1
Number of total cancer research papers per country
DE
FR
NL
CA
ES
KR
GR
76
64
46
104
36
21
15
7.1
3.9
5.0
7.0
1.9
6.5
0
19
29
19
10
12
0.1
1.5
39
40
44
24
13
0.6
8.9
22
24
10
12
0.4
4.7
25
40
12
13
1.4
2.9
26
37
8.1
7.5
0.3
1.5
12
11
6.9
4.3
2.0
0.7
14
20
11
6.1
0.1
2.5
0.7
1.1
0.1
1.1
0.1
0
2.3
5.3
1.8
1.0
1.9
0
3.5
1.9
0.1
6.1
0.9
3.0
0.1
8.7
15
3.8
8.3
2.6
0.6
0.3
5.8
5.9
8.6
4.4
1.7
0
0.4
1.5
0.1
0.1
0.1
0.2
0.4
0
119
CN
29
11
3.3
6.9
3.7
1.4
0.1
5.9
0.7
2.6
0.1
3.3
1.0
0.7
AU
29
2.2
4.9
24
6.6
12
4.2
5.7
2.9
0.4
0.5
4.6
2.0
0.8
SE
18
1.7
3.4
11
5.3
4.1
6.9
2.5
1.1
0
0.4
1.9
1.4
0
IN
15
0.5
0.1
1.5
2.2
0.1
0.1
0.1
0.3
1.2
0
0.7
0.9
0
Table 4.9
Matrix of ratios of observed to expected cancer drug research papers per country
Ratio of observed to expected papers per country
US
Number of cancer papers per country
US
JP
IT
UK
DE
FR
NL
CA
ES
KR
GR
CN
AU
SE
IN
0.6
0.8
1.2
1.0
0.9
1.0
2.6
1.2
0.9
0.6
1.2
1.4
0.9
0.8
0.1
0.7
0.7
0.4
0.9
1.4
0.5
2.1
0.0
3.4
0.8
0.7
0.2
1.5
1.1
1.7
1.9
1.1
1.8
0.0
0.3
0.6
1.1
0.8
0.0
1.4
1.4
2.6
1.6
1.2
0.1
0.9
0.8
3.1
1.5
0.2
1.2
2.1
1.0
1.6
0.1
0.7
0.6
1.3
1.1
0.5
3.1
1.0
1.6
0.2
0.4
0.2
2.1
0.8
0.0
1.0
1.2
0.1
0.3
0.0
1.0
1.7
0.0
0.7
0.4
0.1
1.2
1.4
0.6
0.0
0.0
0.8
0.2
1.2
0.5
0.1
0.0
4.1
0.7
0.0
2.5
0.1
0.7
0.6
0.0
3.3
1.5
0.6
0.7
0.5
JP
1.4
IT
0.8
0.0
UK
0.7
0.2
1.0
DE
0.7
0.2
0.5
1.5
FR
0.6
0.1
0.8
1.5
1.2
NL
0.6
0.1
0.7
1.8
1.7
2.4
CA
1.6
0.2
0.5
1.1
0.8
0.7
0.7
ES
0.7
0.1
1.1
1.4
1.5
2.1
2.0
1.2
KR
1.3
1.9
0.0
0.3
0.3
0.6
0.1
1.0
0.1
GR
0.7
0.0
0.9
2.6
0.9
2.1
1.2
0.8
2.0
0.0
CN
1.0
1.3
0.5
0.9
0.7
0.4
0.0
2.2
0.5
1.8
0.0
AU
0.7
0.1
0.4
2.9
1.1
1.8
0.8
1.9
0.8
0.2
0.1
1.3
SE
0.5
0.1
0.5
1.6
1.0
1.0
2.4
1.4
0.7
0.0
0.2
0.5
1.2
IN
1.6
0.2
0.1
0.6
1.1
0.1
0.1
0.1
0.3
0.9
0.0
1.6
2.4
Note: Cells have been tinted: > 2.0 in bright green, > 1.41 in light green, < 0.71 in pale yellow, and < 0.50 in pink.
120
0.0
0.0
[II] Countries involvement in research for 19 selected drugs
Table 4.10 shows that there is a big variation in the relative emphasis the
different countries place on research in each of the 19 drugs. This pattern is seen
more readily if the values of observed:expected paper counts are calculated. For
example, the expected UK output of papers on alemtuzumab (ALE) is 447 x the UK
overall fractional percentage presence (7.06%) = 31.6, whereas the actual output
was 143, showing a relative concentration of 143/31.6 = x 4.53. Naturally, there are
also drugs where the relative concentration of the UK is less than unity. Table 4.11
shows the values, with the cells tinted to reveal the ones where the values depart
from unity, up- or downwards.
Almost all the 19 drugs have countries with a particular interest in them,
highlighted in bright green, or for some in pale green, and conversely most of the
countries have done more work than average on some selected drugs. We note that
two of the three drugs developed by AstraZeneca (anastrozole and tamoxifen) and
the one developed by SmithKline Beecham (lapatinib) all have a strong UK presence;
the one developed by Aventis (docetaxel) has a strong French presence; and the one
developed by Schering AG (temozolomide) has a strong German presence.
121
Table 4.10
Cancer drug paper ouputs in 15 countries for 19 selected drugs (fractional counts)
US
JP
IT
UK
DE
FR
NL
CA
ES
KR
GR
CN
AU
SE
IN
ALE
146
7.0
29
143
24
5.1
6.0
4.3
4.0
4.0
3.3
4.0
6.0
12
0.0
ANA
56
7.4
13
47
7.8
5.4
1.3
3.9
4.7
0.0
3.0
3.0
3.3
0.2
2.0
BEV
306
28
30
25
95
24
12
11
24
22
14
8.1
10
4.3
11
BOR
279
23
42
16
38
18
10
5.8
20
13
11
22
5.4
1.5
0.0
CAP
158
46
66
64
39
34
16
8.1
21
49
22
14
10
3.0
1.0
CAR
912
266
223
193
162
109
119
50
52
10
91
26
45
22
8.2
CET
99
9.4
35
8.6
34
27
4.0
1.4
13.0
4.2
3.9
6.5
1.5
0.9
0.0
CIS
3223
1433
845
472
533
485
436
293
204
257
132
233
127
126
182
DOC
630
247
158
68
106
203
70
51
67
47
123
52
29
10
7.1
EXE
21
2.0
26
13
5.8
2.0
1.5
6.5
1.4
0.0
5.0
0.0
0.3
1.6
2.0
GEF
194
203
77
51
26
27
8.9
15
11
26
8.0
18
5.1
5.1
6.0
IRI
414
442
97
42
63
149
45
22
43
50
53
10
25
8.2
6.0
LAP
47
2.0
3.2
9.9
3.1
1.8
1.3
0.7
2.5
2.0
0.1
0.4
1.3
0.0
0.2
SUN
101
5.5
10
4.5
14
18
3.1
10
4.6
5.0
3.0
1.9
3.6
1.0
0.0
TAM
1484
224
264
661
170
226
88
184
55
37
44
33
62
111
73
TEM
242
18
77
93
50
21
17
16
8.3
8.7
16
6.3
10
2.1
5.0
TRA
221
41
64
31
41
32
6.9
30
26
6.0
9.1
3.9
11
8.7
2.5
VBL
692
107
108
77
66
97
37
63
18
3.0
20
5.5
23
35
22
VCR
822
211
144
148
120
87
60
65
34
10
24
33
35
33
32
Total
9452
3041
2152
2029
1493
1484
886
796
571
483
493
476
401
377
358
122
Table 4.11
Relative research concentration of the 15 countries for 19 selected drugs (1963-2009)
US
JP
IT
UK
DE
FR
NL
CA
ES
KR
GR
CN
AU
SE
IN
ALE
1.0
0.1
0.9
4.5
1.0
0.2
0.4
0.3
0.5
0.5
0.4
0.5
1.0
2.0
0.0
ANA
0.9
0.4
0.9
3.4
0.8
0.5
0.2
0.7
1.2
0.0
0.9
0.9
1.2
0.1
0.8
BEV
1.2
0.3
0.5
0.5
2.4
0.6
0.5
0.5
1.6
1.7
1.1
0.6
0.9
0.4
1.1
BOR
1.5
0.4
1.0
0.4
1.3
0.6
0.6
0.4
1.9
1.4
1.1
2.4
0.7
0.2
0.0
CAP
0.7
0.7
1.3
1.4
1.1
1.0
0.8
0.4
1.6
4.4
1.9
1.3
1.1
0.3
0.1
CAR
1.1
1.0
1.2
1.1
1.2
0.8
1.5
0.7
1.0
0.2
2.1
0.6
1.3
0.7
0.3
CET
1.0
0.3
1.6
0.4
2.2
1.8
0.4
0.2
2.2
0.8
0.8
1.3
0.4
0.2
0.0
CIS
1.0
1.3
1.1
0.6
1.0
0.9
1.4
1.0
1.0
1.5
0.7
1.4
0.9
0.9
1.4
DOC
0.9
1.1
1.0
0.5
1.0
1.9
1.1
0.9
1.6
1.3
3.4
1.5
1.0
0.4
0.3
EXE
0.6
0.2
3.3
1.8
1.1
0.4
0.5
2.2
0.7
0.0
2.8
0.0
0.2
1.2
1.5
GEF
0.8
2.6
1.4
1.0
0.7
0.7
0.4
0.7
0.7
2.1
0.6
1.5
0.5
0.5
0.6
IRI
0.8
2.6
0.8
0.4
0.8
1.8
0.9
0.5
1.4
1.9
2.0
0.4
1.1
0.4
0.3
LAP
1.7
0.2
0.5
1.7
0.7
0.4
0.5
0.3
1.5
1.4
0.1
0.3
1.1
0.0
0.2
SUN
1.6
0.3
0.7
0.3
1.3
1.8
0.5
1.8
1.2
1.5
0.9
0.6
1.3
0.4
0.0
TAM
1.0
0.5
0.8
2.1
0.7
1.0
0.6
1.5
0.6
0.5
0.6
0.4
1.0
1.9
1.3
TEM
1.1
0.3
1.6
2.0
1.5
0.6
0.8
0.9
0.6
0.8
1.4
0.6
1.1
0.2
0.6
TRA
1.1
0.6
1.3
0.7
1.2
1.0
0.4
1.7
2.0
0.6
0.8
0.4
1.2
1.0
0.3
VBL
1.2
0.6
0.8
0.6
0.7
1.0
0.7
1.3
0.5
0.1
0.6
0.2
0.9
1.5
1.0
VCR
1.1
0.8
0.8
0.9
1.0
0.7
0.8
1.0
0.7
0.2
0.6
0.8
1.1
1.0
1.1
Note: Cells have been tinted: > 2.0 in bright green, > 1.41 in light green, < 0.71 in pale yellow, and < 0.50 in pink.
123
Data was also obtained on outputs of the 15 leading countries for all cancer
drugs in the WoS in 1994-2008, presented as integer counts. Table 4.12 shows the
comparison between their percentage presence in this data set with the
corresponding figures for the 19 selected anti-cancer drugs in the same years. The
differences in percentage presence are mostly very small, but the UK’s presence is
higher here (since four of the 19 drugs were developed by UK companies) and
China’s is lower.
Table 4.12
Global cancer drug research in 15 countries for all drugs (ALL) and 19
selected cancer drugs (19D) (%, integer counts) (1994-2008)
Country
ALL
19 D
Country
ALL
19 D
US
35.4
35.9
FR
6.8
6.6
JP
11.1
11.8
NL
4.3
IT
9.2
8.9
CA
UK
7.0
9.0
DE
7.6
6.4
Country
ALL
19 D
GR
2.0
2.0
4.4
KR
2.1
1.8
4.2
3.9
AU
2.0
2.0
ES
2.7
2.7
SE
1.9
1.7
CN
3.1
1.9
IN
1.6
1.4
4.3.3. Site specific research in cancer drug research
Most of the 19 drugs have been tested for their utility in treating many different
cancer manifestations, only four of them have been tested on eight or fewer
manifestations. Nevertheless, it does appear that the drugs have been tested more
in some cancers than others, shown by the relative application compared with norm
values of each drug and manifestation (Table 4.13).
Data was obtained on research outputs of all cancer drugs against particular
cancer manifestations (1984-2008), compared to research outputs for the 19
selected drugs (Table 4.14) and also to the relative burden for the 16 cancer
manifestations in 15 leading countries collectively (Figure 4.5). [The relative burden
has been weighted to take account of the relative numbers of papers on cancer
drugs, so that the USA has the highest weighting and India the lowest. This allows
comparisons between perceived overall burden and the cancer drug research
portfolio.]
124
Table 4.13
Selected 19 cancer drugs
Research paper outputs: 19 cancer drugs per top 16 cancer sites (1963-2009)
CIS
TAM
CAR
VCR
DOC
VBL
IRI
BEV
GEF
CAP
TEM
TRA
BOR
ALE
CET
SUN
ANA
EXE
LAP
MAM
0.2
3.6
0.3
0.3
1.8
0.3
0.1
0.4
0.5
1.7
0.1
5.0
0.1
0.0
0.1
0.2
5.0
5.4
4.0
LUN
1.3
0.0
2.4
0.5
2.0
0.4
1.3
0.4
5.3
0.2
0.2
0.3
0.3
0.1
0.8
0.2
0.0
0.0
0.1
OVA
1.7
0.7
2.7
0.2
0.6
0.4
0.4
0.6
0.1
0.2
0.1
0.2
0.2
0.1
0.2
0.1
0.6
0.5
0.2
COL
0.4
0.2
0.1
0.3
0.1
0.0
8.5
3.6
1.1
7.6
0.1
0.0
0.3
0.0
10.6
0.7
0.1
0.5
0.0
MOU
1.9
0.1
1.5
0.5
1.6
0.5
0.2
0.3
1.3
0.4
0.0
0.2
0.6
0.0
2.7
0.0
0.0
0.0
0.0
LIV
0.9
1.8
0.3
0.5
0.5
1.1
2.3
1.0
0.5
1.1
0.2
0.2
0.8
1.1
1.5
0.9
0.2
0.3
0.0
Top 16 cancer types
UTE
LEU
STO
0.5
0.4
1.4
4.4
0.1
0.2
0.8
0.8
0.4
0.2
5.0
0.3
0.2
0.2
2.0
0.2
1.0
0.2
0.1
0.4
3.0
0.0
0.1
0.5
0.1
0.5
0.6
0.1
0.1
3.4
0.1
0.7
0.2
0.3
0.1
0.4
0.0
4.8
0.5
0.0
9.9
0.2
0.0
0.0
1.1
0.0
0.9
4.4
2.6
0.0
0.2
0.0
0.0
0.0
0.4
0.0
0.5
LYM
0.3
0.1
0.4
4.8
0.1
0.7
0.5
0.1
0.1
0.0
0.7
0.0
16.3
2.6
0.0
0.0
0.0
0.0
0.0
MEL
1.3
1.0
0.7
1.2
0.5
1.3
0.1
0.7
0.5
0.2
7.4
0.0
0.5
0.1
1.3
1.1
0.3
0.0
0.0
PRO
0.2
0.7
0.8
0.1
8.2
0.8
0.2
0.4
2.0
0.7
0.1
0.8
1.8
0.0
0.5
1.4
1.4
0.0
0.0
Note: Cells tinted to show high values (> 8.0, turquoise; > 4.0, bright green; > 2.0, mid green; > 1.41, pale turquoise; > 1.0 pale yellow)
125
CER
2.0
0.3
1.4
1.1
0.4
0.5
0.7
0.1
0.1
0.6
0.0
0.1
0.1
0.0
0.7
0.0
0.0
0.0
0.0
BLA
2.0
0.2
1.4
0.5
0.5
2.7
0.1
0.0
1.4
0.1
0.0
0.3
0.7
0.0
0.0
0.5
0.0
0.0
3.5
PAN
1.0
0.6
0.3
0.3
1.6
1.2
2.0
0.6
1.2
3.0
0.5
0.7
2.0
2.5
2.6
1.1
0.0
0.0
0.0
OES
2.1
0.0
1.2
0.1
1.7
0.2
1.7
0.0
1.1
2.6
0.0
0.4
0.5
0.0
0.5
0.0
0.0
0.0
0.0
Table 4.14
Cancer drug research outputs in 16 cancer sites for all drugs (ALL) and 19 selected drugs (19 D) (1984-2008)
Site
ALL
%
19 D
%
Ratio
Site
ALL
%
19 D
%
Ratio
BLA
543
1.16
281
1.11
0.95
MEL
760
1.62
434
1.71
1.05
CER
415
0.89
376
1.48
1.67
MOU
1311
2.80
742
2.92
1.04
COL
2286
4.89
954
3.76
0.77
OES
294
0.63
205
0.81
1.29
LEU
3414
7.30
606
2.39
0.33
OVA
1822
3.89
1476
5.81
1.49
LIV
1437
3.07
721
2.84
0.92
PAN
715
1.53
231
0.91
0.60
LUN
3443
7.36
2407
9.48
1.29
PRO
839
1.79
371
1.46
0.82
LYM
2458
5.25
625
2.46
0.47
STO
1304
2.79
700
2.76
0.99
MAM
4448
9.51
3265
12.86
1.35
UTE
714
1.53
730
2.88
1.88
Note: Sites where the 19 drug papers are relatively concentrated (> 1.41) tinted light green; where RC < 0.71 tinted pale yellow; where RC < 0.5 tinted pink.
126
Figure 4.5
Cancer drug paper outputs (1994-2008) versus cancer burden of disease
(% DALYs) (2004) (weighted by the countries’ presence in cancer drug
research)
Cancer drug papers, 1994-2008, %
10
breast
lung
leukaemia
lymphoma
5
colorectal
ovary
liver
mouth stomach
prostate
uterus
pancreas
melanoma cervix
bladder oesophagus
0
0
5
10
15
20
25
% of cancer DALYs for 15 countries
Research work on the 19 selected drugs clearly concentrates on gynaecological
cancers (uterine, cervical, ovarian) and to a lesser extent on breast cancer, on the
other hand, there is less work on leukaemia and lymphoma drugs. The comparison
with the disease burden suggests that although for many sites the amount of
research is about right, it is much too low for some relatively neglected cancers such
as lung, colorectal, oesophageal and pancreatic cancer. Only leukaemia seems to be
somewhat over-researched, at least in comparison with its disease burden.
[I] National interest in cancer drug research related to site-specific cancer
burden
Further analysis was carried out, again on a fractional count basis, to see if
countries with bigger relative disease burden from particular cancer sites took this
into account with their work on the selected 19 cancer drugs (Table 4.15, 4.16).
127
Table 4.15
Numbers of cancer papers (fractional counts) for the 15 leading countries for 19 selected drugs in 16 cancer sites
AU
CA
CN
DE
ES
FR
GR
IN
IT
JP
KR
NL
SE
UK
US
BLA
6
12
5
17
11
12
5
1
19
39
8
5
1
25
94
CER
4
15
4
9
1
7
6
6
34
55
11
7
3
16
150
COL
13
14
9
58
49
96
35
0
142
102
25
29
8
62
267
LEU
13
13
12
38
13
30
12
3
60
81
3
18
18
32
316
LIV
12
20
32
41
14
48
4
3
51
163
19
9
11
63
190
LUN
23
49
56
97
84
114
98
2
272
536
86
68
12
91
692
LYM
9
19
12
50
24
25
13
15
73
63
12
14
7
47
277
MAM
56
128
26
153
77
183
75
31
365
188
33
65
91
385
1117
MEL
20
11
3
40
8
16
13
4
50
16
0
14
11
36
190
MOU
11
11
14
60
23
46
18
8
80
90
12
24
14
25
296
OES
1
2
7
14
5
7
1
4
6
61
9
6
3
8
67
OVA
22
61
35
66
13
64
23
5
150
163
9
73
13
121
554
PAN
1
5
3
20
2
23
11
0
22
27
7
4
2
17
89
PRO
7
18
3
11
5
25
6
0
40
26
3
6
4
14
220
STO
10
2
36
46
15
31
14
4
62
233
81
10
4
32
105
UTE
5
17
2
26
11
34
22
6
49
73
3
13
16
85
252
128
Table 4.16
Ratios of observed to expected cancer drug research paper outputs for 15 countries for 16 cancer sites
AU
CA
CN
DE
ES
FR
GR
IN
IT
JP
KR
NL
SE
UK
US
BLA
1.5
1.5
0.9
1.1
1.9
0.7
1.0
0.2
0.9
1.2
1.5
0.5
0.3
1.2
1.0
CER
0.7
1.3
0.6
0.4
0.1
0.4
0.8
1.2
1.1
1.3
1.6
0.5
0.6
0.5
1.1
COL
0.8
0.5
0.5
1.1
2.4
1.8
1.9
0.0
1.8
0.9
1.4
0.9
0.6
0.8
0.8
LEU
1.2
0.6
0.9
0.9
0.8
0.7
0.9
0.3
1.0
1.0
0.2
0.8
1.7
0.6
1.2
LIV
1.1
0.9
2.5
1.0
0.9
1.2
0.3
0.3
0.9
1.9
1.4
0.4
1.0
1.1
0.7
LUN
0.6
0.7
1.3
0.7
1.6
0.9
2.2
0.1
1.4
2.0
2.0
0.9
0.4
0.5
0.8
LYM
0.8
0.9
1.0
1.3
1.6
0.6
1.0
1.6
1.3
0.8
0.9
0.6
0.7
0.9
1.1
MAM
1.1
1.3
0.4
0.8
1.1
1.0
1.2
0.7
1.3
0.5
0.5
0.6
1.9
1.5
0.9
MEL
2.8
0.7
0.3
1.5
0.8
0.6
1.4
0.6
1.3
0.3
0.0
0.9
1.7
1.0
1.1
MOU
1.0
0.5
1.0
1.4
1.4
1.1
1.2
0.8
1.3
1.0
0.9
1.0
1.3
0.4
1.1
OES
0.4
0.4
2.0
1.3
1.2
0.7
0.3
1.6
0.4
2.9
2.6
1.0
1.2
0.6
1.0
OVA
1.0
1.4
1.3
0.8
0.4
0.8
0.9
0.2
1.3
1.0
0.3
1.5
0.7
1.1
1.1
PAN
0.3
0.7
0.6
1.5
0.4
1.7
2.4
0.0
1.1
1.0
1.5
0.5
0.6
0.9
1.0
PRO
1.2
1.6
0.5
0.5
0.6
1.2
0.8
0.0
1.3
0.6
0.4
0.5
0.7
0.5
1.6
STO
0.9
0.1
2.9
1.2
1.0
0.8
1.1
0.4
1.1
2.9
6.3
0.4
0.4
0.6
0.4
UTE
0.5
0.8
0.1
0.6
0.7
0.8
1.6
0.6
0.8
0.9
0.2
0.5
1.5
1.5
1.0
Note: Cell tinting shows high values (> 2.0 in bright green; > 1.41 in pale green) and low values (< 0.71 in pale yellow; < 0.5 in pink).
129
Again, the observed number of papers can be compared with the expected
number on the basis of each country’s overall output and the numbers of papers
concerned with each cancer manifestation (Table 4.17). Ideally, the tinting of the
cells in Table 4.17 should be just the opposite of that in Table 4.5, with countries
with high cancer burden of a particular cancer site carrying out similar amounts of
research. The correlation for individual countries should, in theory, be higher than
for all types of cancer research, as the size of the national markets for drugs to
combat these cancer manifestations are well known to pharmaceutical companies.
In fact, the correlation is very poor for most of the 15 countries, except for China (r2
= 0.76), suggesting there is a national cancer drug research strategy in place.
Australia is fair (r2 = 0.51), mainly because the relatively greatest output is in
melanoma research (x 2.8) of which Australia has high incidences (x 5.0) (Figures 4.6,
4.7)
Figure 4.6
Country specific correlation coefficient of cancer drug paper outputs versus
burden for 16 cancer sites
1
r 2 value
0.8
0.6
0.4
0.2
0
CN
AU
GR
KR
IN
CA
US
IT
ES
FR
UK
NL
Note: US in red; EUR30 countries in blue; rest of the world countries in orange.
130
JP
DE
SE
Figure 4.7
China: cancer drug research output versus burden from 16 cancer sites
3
stomach
Relative research output for cancer site
2.5
liver
2
oesophagus
1.5
ovary
lung
mouth
1 lymphoma
leukaemia
bladder
pancreas
cervix
colorectal
prostate
melanoma breast
0.5
uterus
0
0.0
0.5
1.0
1.5
2.0
Relative burden from cancer site
2.5
3.0
4.3.4. Clinical versus basic cancer research types
For the analysis of research levels, the papers involving each of the 19 selected
drugs were divided into five (and in four cases, only four) quintiles. Overall, the
papers have become slightly more clinical over time, on both as a journal and an
individual paper basis (Figure 4.8).
131
Figure 4.8
Mean research level (RL) of all cancer drug papers in five quintiles
2.5
Paper
Journal
Mean RL
2
1.5
1
63-90
91-97
Years
98-02
03-06
07-09
Note: RL 1 = clinical, RL 4 = basic research
However, the situation with individual drugs varies greatly. First, there are big
differences in the mean research levels of their papers (Figure 4.9): the vinblastine
papers are the most basic and those on capecitabine and bevacizumab are the most
clinical, with the difference being quite large. Second, the individual papers are
mostly more clinical than the journals in which they are published. Third, for a few
drugs the papers become more basic with time (anastrazole and tamoxifen based on
paper titles, and cisplatin and vincristine on both scales). Fourth, for some drugs the
second quintile is much more clinical than the first, but then the subsequent
quintiles become more basic (Figure 4.10). There is a much bigger variation between
the countries in terms of the mean research level of their papers (Figure 4.11).
India and China publish the most basic papers, probably because their clinical
journals are not processed for the WoS, and Greece the most clinical ones. Indian
and Chinese papers are, on average, more clinical than the others in the same
journals, but for most other countries the reverse is true – particularly for those
doing clinical work.
132
Figure 4.9
Mean research level (RL): journal source (RLj) versus title source (RLp) in
19 cancer drug papers (1963 -2009)
2.75
2.5
VBL
GEF
BOR
2.25
LAP
CIS
TAM
CET
2
RL p
Total
VCR
ALE
TEM
1.75
IRI
EXE
1.5
TRA
CET
SUN
ANA
CAR
1.25
BEV
CAP
1
1
1.25
1.5
1.75 RL j
2
Note: RL 1 = clinical, RL 4 = basic research
133
2.25
2.5
2.75
Figure 4.10
Average research level (RL) per time quintile for 6 cancer drugs
3
GEF
Mean RL (paper)
2.5
BOR
TAM
2
SUN
1.5
EXE
DOC
1
Q1
Q2
Q3
Quintile Q4
Q5
Note: RL 1 = clinical, RL 4 = basic research
Figure 4.11
Mean research level (RL) from 15 countries in 19 cancer drug research
papers per paper title (paper) and per journal source (journal)
3
Paper
Journal
M ean Research Level
2.5
2
1.5
1
IN
CN
JP
KR
SE
Wld
UK
US
134
CA
NL
DE
FR
AU
IT
ES
GR
[I] Anti-cancer drug research activity according to clinical development phase
Some of the papers referred specifically to the work being part of a clinical trial,
either Phase I, II or III (occasionally combinations). The percentage of each drug’s
papers that formed part of a clinical trial ranged from below 3% (tamoxifen) to
almost 40% (capecitabine) (Table 4.17).
Table 4.18 shows that Phase II trials dominated, with nearly two thirds of the
total. This was also true for all the individual drugs except three, although the
numbers of papers were not large for these (bortezomib, lapatinib and sunitinib).
Perhaps surprisingly, Phase II trials usually came first, as early as or even earlier than
Phase I trials, as shown in the example time pattern of papers for carboplatin (Figure
4.12). For this drug, the number of papers peaked around 1996, decreased, then
rose again to a second, smaller peak in 2006. Clinical trials papers also showed two
peaks, but this second peak (2006) was higher than the first.
Figure 4.12
Phased carboplatin clinical trials longitudinal paper outputs (3-year
running means)
200
% of papers (3-yr avg)
Carboplatin papers
150
100
Other
Phase III
50
Phase II
Phase I
0
1984
1989
1994
Year
135
1999
2004
Table 4.17
Phased clinical trials paper outputs in 19 cancer drugs (1963 -2009)
Code
Drug name
Total
I
II
III
Trials
%
ALE
alemtuzumab
447
2
10
1
13
2.9
ANA
anastrozole
195
1
6
4
11
5.6
BEV
bevacizumab
758
4
28
10
42
5.5
BOR
bortezomib
550
31
29
5
65
11.8
CAP
capecitabine
659
82
159
18
259
39.3
CAR
carboplatin
2575
294
559
52
905
35.1
CET
cetuximab
297
10
27
3
40
13.5
CIS
cisplatin
10299
368
1118
151
1637
15.9
DOC
docetaxel
2101
221
498
53
772
36.7
EXE
exemestane
105
3
13
2
18
17.1
GEF
gefitinib
749
31
69
6
106
14.2
IRI
irinotecan
1580
216
310
24
550
34.8
LAP
lapatinib
83
7
6
2
15
18.1
SUN
sunitinib
197
6
5
1
12
6.1
TAM
tamoxifen
4555
18
78
33
129
2.8
TEM
temozolomide
658
44
98
4
146
22.2
TRA
trastuzumab
639
8
43
4
55
8.6
VBL
vinblastine
1810
32
105
19
156
8.6
VCR
Vincristine
2378
16
101
31
148
6.2
28752
1195
2795
340
4330
15.1
All
136
Different countries showed different clinical trial outputs, negatively correlated
with the mean research level of their papers (Figure 4.13). Greece produced
relatively the most trials and India the least. Sweden produced fewer than expected
based on the research level of its papers while Korea rather more, largely
attributable to their choice of drugs on which they concentrated their efforts (Table
4.11) – Sweden on alemtuzumab and tamoxifen (fewer than 3% of trials papers) and
Korea on capecitabine and irinotecan (30%) and gefitinib (15%).
Figure 4.13
Percentage cancer drug clinical trials output per mean research level in
15 countries
40
GR
30
% clinical trials
ES
KR
FR
IT
NL
US
AU
CA
DE
W ld
UK
20
10
JP
SE R 2=
0.7
45
6
CN
IN
0
1
1.5
Mean RL
2
2.5
3
4.3.5. Trends in global and regional cancer drug development
There was a gradual shift over time from the USA and the EUR30 countries to the
RoW (Figure 4.14), with the latter group overtaking the USA and seems likely to
overtake EUR30 shortly.
Its recent rise is mainly due to increasing Chinese
publication outputs, showing rapid increases lately after a temporary halt from 200104 (Figure 4.15). This major expansion in scientific output parallels that seen in other
areas of science but not yet on the scale seen in the physical sciences.7
137
Figure 4.14
Geographical distribution of cancer drug papers in three world regions
(USA, EUR 30, RoW) (quintiles, fractional counts) (1963-2009)
50
% of total
40
30
20
EUR %
US%
10
RoW %
0
63-90
91-97
Years
98-02
03-06
07-09
Figure 4.15
Chinese cancer drug papers, 3-year running means (fractional counts)
(1996-2008)
5
% o f total
4
3
2
1
0
1996
1998
2000
2002
Year
138
2004
2006
2008
The pattern shown in Figure 4.14, with decreasing presence since the 1990s of
both the USA and the EUR 30 countries and an increasing presence of the RoW, does
not prevail for all the drugs. First, there is a big variation in the US presence from
almost 60% to barely 20% (Figure 4.16, Table 4.10), similarly in EUR30 countries and
RoW. Second, for two drugs the US presence has increased over time (alemtuzumab
from 10% to 44%; exemestane from 6% to 22%), and for six drugs the EUR30
presence has increased (bortezomib, lapatinib, sunitinib, trastuzumab, vinblastine
and vincristine). The RoW presence has almost always grown, indicating a steady
shift away from the USA and Europe.
Figure 4.16
Distribution of 19 cancer drug papers by geographical region: USA,
EUR30 and RoW (fractional counts)
100%
RoW %
80%
60%
EUR %
40%
20%
US%
0%
LAP BOR SUN BEV
VBL TEM CAR TRA VCR CET ALE TAM CIS DOC ANA
IRI
GEF CAP EXE
Which countries in the RoW have made the largest contribution? Table 4.18
shows the percentage presence in six quinquennia for 10 RoW countries – the six
listed in Table 4.3, plus the next four (Turkey = TR, Israel = IL, Taiwan = TW and Brazil
= BR) and all others.
139
Table 4.18
Global percentage of 10 RoW countries in 19 cancer drug papers (fractional
counts) (1980-2009)
Years
JP
CA
KR
CN
AU
IN
TR
IL
TW BR
Others
80 - 84
5.7
2.4
0.0
0.1
1.9
0.6
0.0
0.5
0.0
0.1
3.2
85 - 89
6.1
3.2
0.1
0.4
1.8
1.3
0.0
1.2
0.0
0.2
3.5
90 - 94
9.9
3.0
0.1
0.3
1.1
1.8
0.2
1.4
0.5
0.1
3.0
95 - 99
12.7
3.3
0.4
0.6
1.2
1.4
0.6
1.7
0.8
0.4
3.6
00 - 04
12.6
2.5
1.5
1.5
1.4
0.9
1.5
0.8
1.2
0.6
3.1
05 - 09
11.4
2.6
3.9
3.6
1.5
1.3
1.8
0.6
1.4
0.9
3.9
30 yrs
10.9
2.8
1.7
1.7
1.4
1.3
1.1
1.0
0.9
0.5
3.5
Although Korea, China, Turkey, Taiwan and Brazil have increased their outputs
both absolutely and relatively, others have declined relatively from an earlier peak.
This is greatest for Israel, whose output has even declined in absolute terms from
1995-99.
4.3.6. Funding of cancer drug research
The analysis of the addresses for the presence of names of pharmaceutical
companies (Table 4.6) yielded their paper outputs (Table 4.19). The 12 companies
developing one or more of the 19 selected drugs were involved in a total of 1,295
papers, in addition the other 14 leading companies were involved in 337 papers. In
total, 1,589 papers had a pharmaceutical company address (5.5%); in addition there
were papers whose addresses included smaller pharmaceutical and biotech
companies not listed in Table 4.6. Each papers was examined for each of the 19
individual drugs to see what part had been played by the drugs’ developers both
before and after marketing approval (Table 4.20).
140
Table 4.19
Intramural papers in 19 cancer drugs per phama company (1963-2009)
Code
VAZ
ZAT
BMS
HLR
LLL
SKB
MLF
PUJ
PFZ
Company
Papers
Aventis Pharma
274
AstraZeneca
173
Bristol Myers Squibb
155
Hoffmann La Roche
126
Eli Lilly
113
SmithKline Beecham
95
Millennium
79
Pharmacia Upjohn
76
Pfizer
71
Code
MRK
SCH
IKL
JJJ
SIG
AMN
EMD
WYH
ABB
GNH
GLX
NVP
Genentech
Glaxo Wellcome
Novartis
67
51
51
TAK
EIS
BOI
DII
Daiichi Sankyo
50
BGN
Company
Merck & Co
Schering Plough
Imclone Systems
Johnson & Johnson
Schering AG
Amgen
Merck KgaA
Wyeth
Abbott
Laboratories
Takeda
Eisai
Böhringer
Ingelheim
Biogen
Papers
35
34
32
32
30
19
17
14
13
10
9
4
2
Table 4.20
Pre- and post- marketing approval paper output in 19 cancer drugs by
their developing pharmaceutical company versus other companies
Drug
Company
All
paper
s
Pre-MA:
Developing
Company
Pre-MA:
Other
Pharma
MA
year
Post-MA:
Company
Post-MA:
Other
Pharma
ALE
ANA
BEV
BOR
CAP
CAR
CET
CIS
DOC
EXE
GEF
IRI
LAP
SUN
TAM
TEM
TRA
VBL
VCR
Total
MLF
ZAT
GNH
MLF
HLR
BMS
IKL
BMS
VAZ
PUJ
ZAT
PUJ
SKB
PFZ
ZAT
SCH
GNH
LLL
LLL
-
447
195
758
550
659
2575
297
1029
9
2101
105
749
1580
83
197
4555
658
639
1810
2378
2875
2
3
15
22
62
73
73
18
60
171
22
79
23
39
26
53
27
17
14
8
805
5
37
17
25
25
70
30
292
74
10
10
162
1
6
95
18
33
34
35
979
200
200
2
200
6
200
6
199
8
198
9
200
4
197
8
199
6
200
5
200
3
199
6
200
7
200
7
198
6
199
9
200
6
196
5
196
3
0
26
12
42
11
21
3
4
50
22
11
2
13
13
0
12
11
0
0
253
2
0
1
3
0
1
2
0
0
2
0
28
0
5
6
2
21
0
0
73
141
Overall, the number of papers involving companies other than the primary
developer exceeds those involving the drug development company, but as expected,
the latter dominates in the years leading up to marketing approval. This pattern
holds true fot all drugs except irinotecan, tamoxifen, trastuzumab and the two longestablished Eli Lilly drugs vinblastine and vincristine. These drugs all have more
papers involving other companies than the development company as do several
others such as anastrozole and cisplatin.
[I] Funding of cancer drug research by sector
The main analysis was in terms of the four main sectors: government, privatenon-profit, industry and international.
For the 19 selected cancer drugs the
breakdown of financial funding was analysed (Table 4.21). The sample sizes varied by
about 6:1, but the complete set of papers for the different drugs varied by more than
100:1. The tinted cells in the five right-hand columns of show there is a substantial
variation in the amount of support from the different sectors for the 19 drugs.
Bortezomib and vinblastine receive most from government (see also the blue bars in
Figure 4.17) and exemestane and anastrozole the least; there is relatively less
variation in the support from private-non-profit sources although temozolomide
benefits most; exemestane, followed by capecitabine and anastrozole, have the
most support from industry (red bars in Figure 4.17). There is very little international
support for any of the drugs. Papers with no funding acknowledgements must be in
practice funded, normally they would be supported by university or hospital funds,
which in Europe would come from national or regional governments.
142
Table 4.21
Funding sources in 19 selected cancer drug papers (1963-2009)
ALE
ANA
BEV
BOR
CAP
CAR
CET
CIS
DOC
EXE
GEF
IRI
LAP
SUN
TAM
TEM
TRA
VBL
VCR
All
Found
83
60
97
96
121
141
64
302
159
55
111
152
48
75
173
102
115
113
130
1953
GOV
37
7
19
53
30
38
14
129
55
8
45
57
10
28
74
38
35
61
62
728
PNP
38
26
37
51
41
54
26
140
57
14
48
51
19
22
66
60
49
43
56
798
INDY
25
32
21
34
65
42
22
62
75
38
40
57
22
36
45
28
29
19
14
609
INTL
1
1
0
0
1
0
0
5
4
1
0
1
0
1
1
4
2
1
0
23
NON
18
12
33
13
23
39
16
60
31
10
16
34
8
20
41
10
29
21
36
421
GOV r
1.20
0.31
0.53
1.48
0.67
0.72
0.59
1.15
0.93
0.39
1.09
1.01
0.56
1.00
1.15
1.00
0.82
1.45
1.28
PNP r
1.12
1.06
0.93
1.30
0.83
0.94
0.99
1.13
0.88
0.62
1.06
0.82
0.97
0.72
0.93
1.44
1.04
0.93
1.05
INDY r
0.97
1.71
0.69
1.14
1.72
0.96
1.10
0.66
1.51
2.22
1.16
1.20
1.47
1.54
0.83
0.88
0.81
0.54
0.35
INTL r
1.02
1.42
0.00
0.00
0.70
0.00
0.00
1.41
2.14
1.54
0.00
0.56
0.00
1.13
0.49
3.33
1.48
0.75
0.00
NON r
1.01
0.93
1.58
0.63
0.88
1.28
1.16
0.92
0.90
0.84
0.67
1.04
0.77
1.24
1.10
0.45
1.17
0.86
1.28
Note: Governments (GOV), Private-non-profit (PNP), Industry (INDY) and International Organisations (INTL). No funding is also given (NON). Ratios in right
hand columns are to percentages for all drug papers, and are tinted according to the scheme used elsewhere.
143
Figure 4.17
Funding sources in 19 cancer drug papers (1963-2009)
150
% INTL
100
%of papers
% INDY
% PNP
50
% GOV
0
BOR
TEM
ALE DOC
GEF
SUN
CAP
CIS
EXE
All
ANA
VBL
IRI
TAM
LAP
VCR
TRA
CET
CAR
BEV
Note: For drug codes, see Table 4.1. Totals often add to more than 100% because many papers
acknowledged funding from multiple sources.
Variation in longitudinal support for drugs with sufficient papers was completed,
6 drugs had 130 or more papers with funding data and chosen for a funding analysis
in five quintiles (Figure 4.18). There appears to be a modest reduction in the amount
of support over time, both of government and industrial funding between the first
and second quintiles, though the latter increases again subsequently to about 27%.
Private-non-profit funding is fairly constant averaging 39% for these six drugs.
Figure 4.18
Funding sources for 6 out of 19 cancer drugs* in different time quintiles
125
% IN TL
%of papers
100
75
% IN DY
50
% PN P
25
% GOV
0
1
2
3
Quintile
4
5
Note: Government = GOV, private-non-profit = PNP, industry = INDY, international = INTL,
*6 drugs = carboplatin, cisplatin, docetaxel, irinotecan, tamoxifen and vincristine
144
Variation in sectoral support for papers from different countries was examined
on an integer count basis for the 15 leading countries (Table 4.22, Figure 4.19).
Sample sizes were not modified to take account of the much smaller numbers of
papers from lesser-producing countries, for example the sample of Chinese papers is
only 20, and that of Indian papers only 11, whereas there are 761 US papers.
Figure 4.19
Funding sources for cancer drug papers in 15 leading countries (19632009)
150
% INTL
125
% of papers
100
% INDY
75
% PNP
50
25
% GOV
0
UK
CA
FR
US AU NL
SE
IT
DE Wld KR
ES
JP
CN
IN
GR
Note: For country codes, see Table 4.3. Government = GOV, private-non-profit = PNP, industry =
INDY, international = INTL.
145
Table 4.22
Funding sources for cancer drug papers in 15 countries: Ratio of percent of national papers to world mean (1963-2009)
Country
US
JP
IT
UK
DE
FR
NL
CA
ES
KR
GR
CN
AU
SE
IN
Found
761
201
183
289
134
157
74
62
72
27
40
20
43
35
11
GOV r
1.2
1.2
1.0
0.7
0.8
0.9
0.9
1.3
0.9
1.6
0.2
1.6
0.7
0.4
0.7
PNP r
1.2
0.6
1.2
1.5
0.8
1.1
1.3
1.0
0.8
0.5
0.7
0.4
1.4
1.7
0.2
INDY r
1.2
1.0
1.1
1.5
1.6
1.7
1.2
1.4
1.0
0.8
0.6
0.6
1.5
1.1
1.2
INTL r
0.2
0.0
1.4
1.5
1.3
4.3
3.4
0.0
2.4
0.0
0.0
0.0
2.0
4.9
0.0
Note: Cells have been tinted: > 2.0 in bright green, > 1.41 in light green, < 0.71 in pale yellow, and < 0.50 in pink.
146
The number of internationally-funded papers are too small for the analysis to be
meaningful, but there are several interesting trends. The far eastern countries
(China, Japan, Korea) rely mainly on government sources with very little private-nonprofit sources, while both China and Korea have little industry support from industry.
Of the European countries, Greece and Sweden have little government support,
however, Sweden together with the UK enjoys high private-non-profit funding.
Germany, France and the UK have the largest proportion of support from industry,
noticeably more than the USA. Canada and the USA receive more government
support than any of the European countries.
Finally, we examined the sectoral support for drugs intended for use in the 16
cancer sites (Table 4.23). Data for cervical and oesophageal cancer were omitted
due to insufficient papers (7 and 5 respectively). The differences are relatively minor
between the different sites, particularly when accounting for small paper sample size
(13 of the 16 cancer sites were less than 100 papers). Leukaemia, followed by
lymphoma, gets most support from government; the situation with respect to
private-non-profit funders is similar. Industry relatively favours research on the
application of drugs to breast and colorectal cancer.
147
Table 4.23
Funding sources for cancer drug research papers in 16 cancer manifestations (1963-2009)
BLA
COL
LEU
LIV
LUN
LYM
MAM
MEL
MOU
OVA
PAN
PRO
STO
UTE
Found
GOV
PNP
INDY
18
6
7
4
115
24
43
47
66
38
35
16
45
17
13
13
165
54
71
55
59
28
34
21
306
82
128
129
42
19
23
10
32
14
13
9
53
21
27
19
20
6
9
4
30
12
15
11
47
18
13
14
31
8
9
1
% GOV
% PNP
% INDY
33
39
22
21
37
41
58
53
24
38
29
29
33
43
33
47
58
36
27
42
42
45
55
24
44
41
28
40
51
36
30
45
20
40
50
37
38
28
30
26
29
3
GOV r
PNP r
INDY r
0.9
1.0
0.7
0.6
0.9
1.3
1.5
1.3
0.8
1.0
0.7
0.9
0.9
1.1
1.1
1.3
1.4
1.1
0.7
1.0
1.4
1.2
1.3
0.8
1.2
1.0
0.9
1.1
1.2
1.1
0.8
1.1
0.6
1.1
1.2
1.2
1.0
0.7
1.0
0.7
0.7
0.1
Note: For codes about the 16 manifestations of cancer, see table 4.4. Upper section: actual numbers of papers; middle section: percent of papers concerning this
site; lower section: ratio of these percentages to mean for all papers (cells tinted to show values > 1.41 in pale green, < 0.71 in pale yellow, and < 0.5 in pink).
148
[II] Leading funders of cancer drug research
The 1,953 papers whose funding had been recorded acknowledged a total of 2,833
funding sources. These were tallied in order to list the leading sources of support for cancer
drug research, under the three sectoral categories (Tables 4.24, 4.25). The individual
institutes of the US National Institutes of Health have been grouped together, as some
authors acknowledge the institute, and some just the NIH. Similarly, acknowledgements to
subsidiary companies have been grouped under the main parent company, even if it was
not the owner at the time of the research, with the sole exception of Genentech Inc. Table
4.24 shows the dominant position of the US National Institutes of Health / National Cancer
Institute in funding cancer drug research, with support to over one third of the US papers.
Table 4.24
Governmental organisations supporting cancer drug research (1963-2009)
Code
NIH
JED
PHS
MRC
SAP
DFG
DOD
CRS
CNR
HHS
KRG
CCI
NIZ
VAM
ISO
US
JP
US
UK
IT
DE
US
FR
IT
US
KR
CA
NL
US
Cat'y
GA
GD
GD
GA
GD
GA
GD
GA
GA
GD
GD
GA
GA
GD
INS
FR
GA
Funding body
National Institutes of Health (incl. NCI & others)
Education, Science and Culture, Ministry of
Health & Human Services, Dep't of
Medical Research Council
Health, Ministry of, Rome
Deutsche Forschungsgemeinshaft
Department of Defense
Centre Nationale de la Recherche Scientifique
Consiglio Nazionale delle Ricerche
Agency for Health Care Policy and Research
Education, Ministry of
Canadian National Cancer Institute
Netherlands Cancer Insititute
Veterans Affairs, Dept of
Inst. Nat'l de la Santé et de la Recherche
Medicale
N
365
72
72
46
33
27
20
19
18
16
15
13
12
12
10
Note: GA = government agency; GD = government department. For country codes see Table 4.3.
149
Table 4.25
Non-profit organisations supporting cancer drug research (1963-2009)
Code
CRC
AIR
X12
TXU
DNF
ACS
SKI
RMR
X14
X19
MYO
ALS
ACC
REC
FXC
KIF
SNA
IGY
JPC
NLC
SCA
ULB
WEL
X38
ISO
UK
IT
US
US
US
US
US
UK
US
US
US
US
FR
IT
US
SE
US
FR
JP
NL
SE
BE
UK
JP
Cat'y
CH
CH
FO
MI
FO
CH
NP
HT
HT
NP
NP
CH
CH
NP
NP
MI
FO
NP
CH
CH
CH
MI
FO
MI
Funding body
Cancer Research UK
Associazione Italiana per la Ricerca sul Cancro
Misc. foundations
University of Texas
Dana Foundation
American Cancer Society
Memorial Sloan-Kettering Cancer Ctr, New York
Royal Marsden Hospital
Misc. hospital trustees
Misc. non-profit
Mayo Clinic and Foundation, Rochester MN
American Lebanese Syrian Association Charity
Association pour la Recherche contre le Cancer
Regina Elena Cancer Institute, Rome
Fox Chase Cancer Center, Philadelphia
Karolinska Institutet, Stockholm
Sinagusa Foundation
Institut Gustave Roussy, Villejuif
Japanese Foundation for Cancer Research, Tokyo
Dutch Cancer Society
Cancerfonden, Stockholm
Universite Libre de Bruxelles funds
Wellcome Trust
Misc. universities
N
99
35
34
31
30
29
29
24
24
23
19
17
13
13
12
12
12
11
11
11
11
11
11
10
Note: CH = collecting charity; FO = endowed foundation; HT = hospital trustees; MI = mixed (academic
funds); NP = other non-profit. For country codes see Table 4.3.
150
4.4. Conclusions and Policy Issues
This chapter examined research papers on 19 selected cancer drugs (articles, notes
and reviews) from the WoS for 1963 to mid-2009. The papers were identified via the drug
names in their titles, including trade and code forms. A total of 28,752 papers were
included in the analysis, after removal of ones that had been identified in error and almost
all were in English.
Papers on the 19 selected drugs rose from 200 annually (1980) to 900 (1995) to over
2,000 annually by 2007-08. The latter figure represents about 4% of all cancer research
output, and half the research paper output of all 150 cancer drugs. The number of papers
on the individual drugs varied from 83 for lapatinib, first marketed in 2007, to 10,299 for
cisplatin from 1978. The leading countries contributing to the research were the USA (33%
of fractional count total), Japan (10.6%), Italy (7.5%) and the UK (7.1%).
International collaboration has increased but is still firmly based on geographical,
historical and linguistic links between nations.
Thus, the USA and Canada each
preferentially select co-authors in the other country, as well as between EU Member States,
especially the Netherlands and the UK. A matrix of the ratios of observed to expected
papers from leading 15 countries for 19 selected drugs showed most drugs having one or
two countries with concentrated output yet conversely with less work on other drugs. The
19 drugs were compared against 16 leading cancer manifestations, finding some cancer
sites favoured over others (e.g. tamoxifen for breast and uterine cancer, cetuximab for
colorectal cancer). However, the research portfolios for these 19 drugs in 15 countries
correlated very poorly with their national cancer burdens of the 16 cancer manifestations,
except for China and to a lesser extent Australia.
Over time, the research levels of the papers (on a scale from clinical = 1 to basic = 4)
became slightly more clinical, but not for all the 19 selected drugs (exceptions were
cisplatin, vincristine, anastrazole, tamoxifen). Work on vinblastine and bortezomib was the
most basic, while bevacizumab and capecitabine the most clinical. Papers from India and
China were the most basic, likely as their national clinical journals are not covered in the
WoS, and those from Spain and Greece the most clinical. About 15% of the papers
151
described phased clinical trials, mostly Phase II. Greece produced most of such trials (34%)
and India the least (2%), and negatively correlated with the research level of the countries’
papers.
Over the period of analysis, the geographical balance shifted from the USA and Europe
to the RoW, particularly China which accounted for almost 5% of global output by 2008.
The US presence varied between 57% for lapatinib to 20% for exemestane, and increased
over time for alemtuzumab and exemestane.
In the papers’ addresses, the presence of 26 leading pharma companies including the 12
associated with development of the 19 selected drugs, occurred for 1,589 papers (5.5%).
Leaders were Aventis (274 papers), AstraZeneca (173) and BristolMyersSquibb (155). In the
years up to and including when initial marketing approval was given, the company
developing the drug dominated the output for 14 of the 19 drugs, as expected.
4.4.1. Policy Conclusions
Modern cancer drug discovery and development ‘starts’ in the early 1970’s, follows a
slow trajectory, and then activity increases substantially between 1990 to 2000. From 2000
onwards the trajectory of outputs increases dramatically while the overall output of cancer
drug development papers globally remains constant at just under 10%. This is entirely the
result of a concomitant major increase in world cancer research activity. We found that the
rate of drug development activity has substantially increased, with more publications per
time period for newer agents than older ones. However, from cumulative data we show the
development of cancer drugs does not stop, even for those with more than 20 years of
marketing authorisation (e.g. Cisplatin 1978, Tamxoifen 1986). The main geographic
locations are the USA, Japan and Europe (primarily Italy, UK, Germany, France) with over
98% of publications in the English language.
Trend analysis shows collaborations at the national level have remained very stable
since the 1990s. International collaboration is still firmly based on geography, linguistic and
cultural ties, although intra-European collaboration has grown since early 2000. Thus
Canada and the USA favour each other, although the USA also has good links with Japanese
and Indian scientists. The three far Eastern countries (China, Japan and Korea) all give
152
above-average preference to each other, and Korea (but not the others) to India. Within
Europe, the Netherlands and the UK appear to play important roles in collaboration, and
there are strong links between the UK and Australia. Perhaps surprisingly, India prefers
Germany to the UK among European countries (this has been observed in other fields as
well), but its relatively preferred partner is Australia. Whilst cultural transmission of science
between geographically or linguistically close countries is to be expected from previous
research, a question mark has always remained about whether whether outreach /
international policies set at the national (or supra-national) level have any affect on the
direction of collaborations and co-operation. Our data on intra-European and USA-China
collaboration support the premise that top-down ‘iron triangles’ can promote co-operation.8
In the former case, the temporal concordance between the evolution of the European
Research Area and the increase in intra-European cooperation in cancer drug development
is strongly suggestive,9 however, the lag time in seeing the benefits of such policies, at least
in this area, is around a decade.
Apart from the Japanese focus on EGFR inhibitors we found no specific trends or
associations between geographic regions and development life-cycle of specifc NMEs. It
appears one or two countries appear take a ‘lead’ in research around a specific cancer drug.
Up to mid-1990s there was a strong association between location of pharmaceutical
companies and research activity, however, this association has loosened with increasing
numbers of NME being developed in a distributed manner. We also found, in absolute terms
and contrary to ‘negitive views’ of Europe’s weakness compared to the USA,10 Europe and
the USA were equal ‘intellectual’ partners in cancer drug research outputs.
In policy terms, discussion of a balanced portfolio has tended to focus either on relative
investments (and activity) in specific cancer research domains (e.g. prevention, fundamental
biology, etc) or in the balance between effort allocation to different disease areas by
pharma companies.11 Relatively little has been asked about the balance in site-specific later
stage cancer drug development. Using this bibliometric approach we have found an
objective way to quantify the relative focus and lacunae in cancer drug development. The
comparison of disease burden suggests that although for many sites the amount of research
is as expected, it is much too low for some cancers such as lung, colorectal, oesophageal and
153
pancreatic. Only leukaemia seems to be somewhat over-producedcompared to its disease
burden – perhaps as a result of using leukaemia as a ‘model system’ for testing many NMEs.
At the country level we found little correlation between the burden of site specific
cancer and associated site specific cancer drug development, confirming bottom-up market
forces are the predominate drivers in most countries. Interesting exceptions are China, and
less so Australia, with clear, longterm correlations between disease burden and site specific
drug development. China in particular has long persued a central cancer drug development
policy in line with its other S&T strategies,12 however, overall there is no evidence that
either approach leads globally to better or worse outcomes in terms of site specific
development. The key policy message is for that some cancers a site specific focus may be
required.
A widely held assumption is that cancer drug discovery and development progresses
through set phases of pre-clinical, mostly basic laboratory, research to eventually clinical
research. Whilst this view may hold true for the absolute extremes of development, our
results show cancer drug development progression mixes both basic and clinical research
over time. There is no simple hand off from one type to the other at any point. Individual
countries also produce either predominantly basic or clinical cancer drug development
research. Thus, cancer drug development policies should cover the full spectrum research,
both clinical and basic.
Cancer drug development between the 1970s to 1990s had some linearity, yet the
emergence of ‘translational’ research has driven increasingly complex, multi-party
collaborations and parallel research at the class as well as individual drug level.13 Most
clinical development occurs at the Phase II stage, however, the ‘clinical development’ phase
continues throughout a drug’s lifespan from pre-MA onwards. Indeed, our data clearly
shows that individual cancer drug development never stops either clinically or pre-clinically.
Unsurprisingly Phase III (large scale clinical trials) only make up a very small proportion of
overall research activity, which has important policy implications. Cancer drugs are
continually ‘in development’ against new indications in addition to being refined with new
schedules, regimens, etc. The old paradigm of cancer drug development ending with its
marketing authorisation is no longer valid in any way, supported by continued publication
production post-marketing.
154
Our data supports current perception that cancer drug discovery and development is
entering a global phase. Outputs from the RoW (in particular China) are set to overtake
those from Europe and the USA, giving some indication of the competitive nature of this
area of drug development and huge opportunities for major breakthroughs. It will be
essential to develop new policies containing collaboration and co-operation to bridge
geographic and socio-cultural gaps between investigators in different countries and regions.
This is no easy task as numerous hurdles block sustainable co-operation.14 At individual drug
level, all three regions contribute in different capacities to overall output but with large
variations (e.g. USA 20%-60%) and increasing RoW share as the the only clear trend.
The current policy paradigm around cancer drug discovery and development views
research activity progression from an exclusively private (industry) based activity to
eventually a mixed economy with both private and public investment in the post-marketing
phase.15 Our findings indicate a much more complex picture with important policy
implications. Drug by drug basis, large variations in government, philanthropic and industry
sectors support were found to contribute to overall drug development. Rationales for this
variability accounting for primarily one funding source or another are often based on a
drug’s life history (e.g. temozolomide primarily produced by academic). What is clear is that
all three sectors are equally important in contributing to drug development. Furthermore,
even the earliest development period have funding contributions eventually brought into
public domain. This is an important point, as industry contribution is underestimated due to
unpublished research activities. Our data clearly shows that public-private partnerships,
even in early stages, is of major importance to the overall development life-cycle. Federal
and philanthropic funders making up public sector support are a mixture of endowed and
collecting charities, as well as ministries and arms-length funding bodies. In the premarketing phase, development is primarily by one company, but post-marketing most of the
publications cite multiple private funders which indicate a multi-sourced flow of private
capital into further development. Our data indicate public-private partnerships are now the
normative model from early pre-clinical to clinical development and beyond into Phase IV.
155
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cancer research in the 6th Framework Programme. Mol Oncol 1: 14–18.
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Appointed Following the Hampton Court Summit and Chaired by Esko Aho, Creating an
Innovative Europe, January 2006.
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7: 639-640.
12. Cheng MH (2007) Cancer research funding in Asia. Molec Onc 1: 135–137.
13. Cambrosio A (2006) Mapping the emergence and development of translational cancer
research. Eur J Cancer 42: 3140–3148.
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15. Kaplan W, Laing R. (November 2004). Priority Medicines for Europe and the World.
WHO/EDM/PAR/2004.7.
156
5. PROMOTING AND SUPPORTING CANCER DRUG R&D
– RESULTS OF A SENIOR SCIENTISTS SURVEY
5.1. Background and Objectives
The purpose of social and public policy in cancer drug development is to understand,
evaluate, interpret and define policies that form priority areas for the future. The existing
literature is replete with studies examining consumer, patient and industry perspectives on
drug development policy, but a key often neglected stakeholder group are those clinicians
and scientists carrying out front-line research into the next generation of anti-cancer
treatments.1-3 Background sources on public policy development in cancer and drug
development per se, such as the Institute of Medicine (IOM) Forum and the Tufts Centre for
the Study of Drug Development, intellectually underpin the objectives framework for this
study of key opinion leader views on anti-cancer public policy.
The objective of this research was to elicit and semi-quantify the views of key clinical
leaders in cancer drug development from Europe and the USA to:
•
Critically examine whether policies affect funding models and, if so, how;
•
Define the scope of public sector involvement in the process of discovery and
research in cancer medicines;
•
Critically evaluate key environmental policies for successful cancer drug
development;
•
Understand which policies are likely to have the greatest pay-back in providing the
correct environment for R&D;
•
Identify the strengths and weaknesses of public-private partnership (PPP) models;
•
Critically examine these models in terms of the balance between policies affecting
public and private sector;
•
State the key policy areas for ‘success’ in anti-cancer drug development; and
•
Compare the relative importance of different policy areas across different domains.
157
5.2. Methodological Approach
In order to elicit the views of senior clinicians and scientists on policy issues around
cancer drug development, we proceeded in three steps: first, we identified the relevant
faculty; second, we developed a tool that would be used for this purpose; and third, after
validating it, we administered that tool to the identified faculty.
5.2.1. Semi-Structured Interviews
From October 2008 until March 2009 we carried out semi-structured interviews with 28
members of the faculty to discuss key policy areas. These interviews took place by phone or
in person lasting 25 minutes to 1.5 hours, and addressed a number of key issues including a
Strengths, Weaknesses, Opportunities and Threats (SWOT) analysis, new drug development
models, regulatory environment and funding.
5.2.2. Faculty: Inclusion Criteria and Demographics
The primary cancer drug development faculty was selected from senior clinical and nonclinical active researchers from across Europe and the USA. The inclusion criteria required
they be active publishers in the last five years and regularly invited to speak at major
conferences on cancer drug development (among others AACR, EORTC, NCI, AACR). The
final list was reviewed for geographic, speciality and gender balance before finalisation.
Questionnaires were sent to all faculty members (n=102) for whom verified contact details
were present. In addition, the questionnaire was forwarded to an additional 16 faculty from
the initial listing.
In order to ensure an accurate analysis of critical data, demographic information was
elicited from the questionnaire including:
•
Age and gender
•
Clinical / non-clinical and research domain (NCE / Biological)
•
Geographic location
As the questionnaire was distributed as ‘open’, additional faculty were added if they
fulfilled the criteria of geography and seniority. All responses were anonymous and faculty
were provided with full details of the purpose of the questionnaire and its future use /
distribution.
158
5.2.3. Questionnaire Development
Between 4th December 2008 and 15th March 2009, 12 members of the selected
faculty were interviewed on a one-to-one basis as part of the semi-structured interviews to
build the questionnaire. This was then externally validated when in beta-version.
In
addition, a review of the background literature was undertaken including review of prior
policy studies and public research funding organisations, this information was incorporated
into the results where relevant.
Four key policy areas were identified:
1. Funding (particularly public sector) - Investment by national bodies (philanthropic
and federal) as well as supra-national initiatives.
2. Environment for R&D - This included basic infrastructure (dedicated beds, laboratory
space, bio-banking etc) and intellectual environment (i.e. training and career
development in early phase clinical trials and pre-clinical drug development).
3. Pubic-private interactions - What PPP models had the faculty experienced? Where
the current deficiencies and how could this be rectified?
4. A variety of distinct areas that were considered essential for the ‘success’ of future
cancer drug development (e.g. regulatory and drug reimbursement).
The results of the qualitative survey were discussed with members of the external
advisory board and other key faculty members. Specific questions were chosen in each area
and responses were built around a semi-quantitative Likert scale. A free text response area
was also provided, due to the need to broadly capture public policy views from this faculty.
The beta-version of the questionnaire was subsequently circulated to ten randomly
chosen faculty members and further evolved following feedback, including adding a
demographic profile section onto the beginning of the questionnaire. The final version was
checked for legibility and time-to-complete (15-20 minutes), and pre-letters were sent to all
faculty members prior to its electronic distribution in July 2009, with a two week deadline
on completion. Follow-up notices were sent one week before deadline and additional
reminder letters were sent two weeks after the deadline
159
5.2.4. Questionnaire Analysis
Responses were entered into a standard Excel spreadsheet and converted into a 10point Likert scale. A Likert item is a statement which the respondent is asked to evaluate
according to any kind of subjective or objective criteria, generally, the respondent’s level of
agreement or disagreement is measured. Usually 5 ordered response levels are used, but in
this case we used a 10-point scale to improve statistical analysis. Sub-group analysis
according to demographic profiles was undertaken. In terms of the other data
characteristics, there was very little difference among the scale formats with regards to
variation around the mean, skewness or kurtosis.
Likert scales may be subject to distortion from several causes. Respondents may avoid
using extreme response categories (central tendency bias); agree with statements as
presented (acquiescence bias); or try to portray themselves or their organization in a more
favourable light (social desirability bias). We have attempted to avoid the acquiescence bias
by providing a scale with equal numbers of positives and negatives. The anonymous nature
of our approach also reduces the social desirability bias.
After the questionnaire was completed, each item was analyzed separately, or in some
cases item responses were summed to create a score for a group of items (summative
scale). We considered individual Likert items as interval-level data due to the 10-point scale,
equidistant adjacent pairing about a mid-category and visual analogue scale with equal
spacing of response levels. Secondary analysis of data treated as ordinal was undertaken to
check internal consistency.
When treated as ordinal data, Likert responses were collated into bar charts, central
tendency summarised by median, mode and mean, dispersion summarised by the range
across quartiles, as well as analysis using non-parametric tests (e.g. Chi-square test, MannWhitney test, Wilcoxon signed-rank test, Kruskal-Wallis test). Responses to several Likert
questions in the questionnaire were summed when questions using the same Likert scale,
defendable as an approximation to an interval scale, and thus treated as interval data
measuring a latent variable and subject to parametric analysis.
160
5.3. Results of the clinician and scientist survey
5.3.1. Interviews with drug development faculty
Policy literature to date has focused almost exclusively on commercial drug
development, while ignoring the roles of public funders and the academic community. In
Europe, public funders of cancer drug development have undergone major environmental
changes since the 2004 introduction of the European Clinical Trials Directive. While funders
and academic institutions have long conformed with the standards of ICH GCP, the new
requirements for laboratory studies to be carried out to GCP (GCLP) in addition to continued
issues surrounding acceptability of rodent-only toxicology, increased administration
associated with Clinical Trials Authorisation process, plus requirements for all clinical trial
supplies to be made to GMP standards in a licensed facilityz have led to perceived and real
down-turns in investigator-driven cancer drug development.
In addition to the changes in regulatory and legal requirements, public funders and host
institutions have also experienced major changes over the last five years in the following
areas: public-private partnerships (PPP), contracts, timeliness and pediatric oncology.
[I] Public-private partnerships
There is not one model governing the interaction between public funders / host
institutions and the myriad of pharmaceutical and biotechnology firms. In the latter, most of
the faculty interviewed were clear that public funders / institutions retained substantial
control over the relationship, including ownership of trial data, protocol design, trial
completion and publication of results. With major pharmaceutical companies, however, the
balance often tipped the other way to almost exclusively developed and run early phase
clinical trials which don’t undergo the peer review mechanisms found in public funders /
zz
When production of clinical trial supplies are contracted out to a third party, there is a obligation by the
trial sponsor to audit the facility ensuring operation to appropriate standards and for QP to confirm clinical
trial materials are made to EU GMP standards. This is a major issue for products being made outside the EU
(e.g. USA), as an EU QP needs to release the product and confirm it conforms to EU GMP standards regardless
of its acceptability elsewhere (e.g. US FDA).
161
institutions. In some cases, the academic faculty had found the protocol development was
conducted with their input and then the trial was run in a third party country.
[II] Contracts
The unanimous view from interviews was a geometric progression in complexity and
time-lines for arranging contracts between parties prior to beginning pre-clinical and clinical
projects. This increased bureaucracy was not only confined to PPP, but also to public-public.
On average, there are 6 to 11 agreements per project, all taking significant time and
negotiation. Complexity increases substantially with advanced biologicals, in particular for
gene therapies suffering from the ubiquitous ‘patent stacking’ problem.
[III] Timeliness
Across the board, it was expressed that time needed for public funders / host
institutions to pursue cancer drug development in either pre-clinical or clinical phases,
particularly the latter, had dramatically increased. A variety of reasons were given including
contract negotiation (see above), lack of major centres with sufficient critical mass and
infrastructure resources (specifically directed at larger Phase II studies), under-funding / low
sourcing from public funders, and time needed to validate PK and primary / secondary PD
processes.
Faculty were clear that public funders / host institutions had played a major role in
cancer drug development over the last twenty years. In addition to the role of national
bodies supporting pre-clinical and clinical development (e.g. UK, National Cancer Institute
(NCI), Cancer Research UK (CRUK)), other organisations such as the Southern Europe New
Drug Organisation (SENDO) have also been instrumental in supporting academic
investigators. However, faculty also stressed this complex funding arrangements between
public and commercial sources have always been around in one form or another. While
there might indeed be a higher attrition rate in publicly supported post-Phase I
development, many of the NME’s were highly novel, providing supplemental proof-ofprinciple data benefiting other programmes; thus the knowledge derived from these studies
was critical to future generations of drug development. Indeed, public funding was
expressed as particularly important to many high risk research areas, such as complex cell
therapies, novel derived antibodies and gene therapeutics.
162
Faculty primarily involved with biologics research were different in this respect to their
colleagues involved with NME as they considered public funding to have driven (and
continuing to drive) the development of very novel biologicals. These faculty were clear this
was a key area for public support, targeting truly risky innovative approaches rather than
developing ‘me too’ or second-in-class medicines. Furthermore, their emphasis on proof-ofconcept studies as a way to improve overall attrition rates and truly novel approaches has
been supported by other studies.1 Again, the importance of both funder and host institution
support was made with notable examples of translation into major advances in cancer drug
discovery (e.g. New Agents Committee of the Cancer Research Campaign, CRUK).
[IV] Paediatric Oncology
The paediatric oncology drug development community had specific key issues. While
paediatric oncology outcomes have improved dramatically over the last thirty years, there
remains large gaps for new medicines. The research community, through International
Society of Paediatric Oncology (SIOPE) and Innovative Therapies for Children with Cancer
(ITCC), has been active in promoting this area at both national and European levels for the
last decade. Their work has clearly identified the major policy areas for drug development in
paediatric oncology.
Each year in Europe, approximately 12,000 new childhood cases of cancer are diagnosed
and approximately 3,000 children succumb to cancer. Childhood cancers differ significantly
from adult cancers in terms of histology and sensitivity to conventional treatments,
explaining why the prognosis of children with cancer has dramatically improved over the
last 40 years. Standard treatments have been developed by academic clinical research
networks at the national, European and international levels (SIOP), however, involvement
by the pharmaceutical industry has been limited. Despite improved paediatric disease-free
survival rates (ca. 65% across all paediatric cancers), cancer is still a life-threatening disease
in children and remains the major cause of death from disease beyond the age of 1 year.
Cure is often only achieved at a substantial cost (major organ toxicity, developmental
abnormalities, secondary tumours). These long-term soliloquy constitute significant
healthcare burden, reducing both life expectancy and quality of life for childhood cancer
survivors.
163
Access for children to innovative targeted therapies is extremely limited in Europe,
partially due to paediatric oncology not representing a large, and hence financially
attractive, area for drug marketing. This limited commercial potential results in
pharmaceutical companies often not undertaking drug development specific for targets only
present in paediatric malignancies.
Failure to develop effective new treatments for childhood cancers is of major concern,
given the consequences of delaying the clinical evaluation of a potentially active drug. As a
consequence, years of socially and economically useful life are lost, both for the child and
the parents, in addition to the tragic human costs to the individual child, family and friends.
In addition to the general lack of paediatric drug development in Europe, major
disparities currently exist between European member states. In some countries, such as the
UK and France, only a small number of experimental studies can be conducted because of
major difficulties in obtaining new drugs for evaluation. In other countries, such as
Germany, every child has the right to receive any drug that is marketed in adults, even if no
safety or efficacy data are available to support its use in children. Furthermore, in many
countries new drugs are not available at all for children, leading to desperate parents
inappropriately transferring terminally ill children to foreign countries for treatment
(particularly the USA).
The regulation on Orphan Medicinal Products, adopted in 1999, has significantly
improved the level of drug development in rare diseases in Europe. On 14th December 2000,
the Health Council adopted a Resolution on Paediatric Medicinal Products.5 In addition, the
EU Regulation on paediatric medicines entered into force in late January 2007.6 This
Regulation aims to establish a legislative framework to fulfil the following main objectives:
•
To increase availability of medicines specifically adapted and licensed for use in the
paediatric population;
•
To increase information available to the patient/carer and prescriber about the use
of medicines in children, including clinical trial data; and
•
To increase high quality research into medicines for children.
164
These will be achieved through a system of requirements and incentives. The main
elements of the finalised Regulation include:
•
The establishment of a new body, the Paediatric Committee, sited at the European
Medicines Agency (EMEA);
•
A requirement for new products and products currently covered by patent
protection to include paediatric data based on a paediatric investigation plan (PIP),
and a six-month extension of the supplementary protection certificate (SPC) if PIP
information is incorporated into the Summary of Product Characteristics (SmPC);
•
For orphan medicinal products, a two-year extension of market exclusivity if
information arising from a completed PIP is incorporated into the SmPC;
•
For off-patent products, a new category of marketing authorisation called the
paediatric use marketing authorisation associated with ten-year data and market
protection;
•
A European database of paediatric clinical trials, partially to be publicly accessible;
•
A requirement to submit paediatric clinical trial data to the regulatory authorities;
•
Co-ordination of a European Paediatric Clinical Trials Network;
•
Funding for the study of off-patent medicines provided through the European
Community Framework Programmes (FP6, FP7); and
•
An identifying symbol on the package of all products authorised for use in children.
The US Food and Drug Administration has implemented similar regulatory initiatives
(Paediatric Exclusivity and Paediatric Rule, 1997), which have significantly increased the
number of paediatric studies.7 These European and international developments are
expected to create a significant demand for pharmaceutical companies to increase the
number of paediatric clinical trials with new anticancer drugs.
During the past 10 years, initiatives have been undertaken by paediatric oncologists in
Europe to promote the clinical evaluation of new anti-cancer compounds in children within
national academic paediatric oncology groups. In 1995, collaboration was established
between the Pharmacology Group of the French Society of Paediatric Oncology (SFOP) and
the New Agent Group of the UK Children’s Cancer and Leukaemia Group (CCLG), now
representing 20 clinical paediatric oncology centres. Other European cooperative groups,
165
such as those in the Netherlands, Italy and Germany, have recently joined this collaboration
and initiated new drug trials.8
In addition to clinical research, high quality and internationally competitive basic
research on the genetics and biology of paediatric malignancies is being performed in
Europe. There is a strong willingness to translate this research into patient benefit, however
at present, there is no mechanism for linking basic genomic research to drug development
and clinical trials.
Therefore, there is an urgent need to integrate and strengthen the existing basic and
clinical academic research activities with commercial sectors at a European level. The recent
call by the EU Network of Excellence to structure clinical research in paediatric oncology in
Europe is a positive step, but more action is needed at both EU and Member State levels.9
The specific policy objectives for paediatric oncology drug development identified by the
ITCC consortiumaa include:
1. Prioritisation and selection of anti-cancer compounds developed by pharmaceutical
companies for adult use through a comprehensive pre-clinical R&D drug evaluation
program to identify compounds that may be also active in paediatric cancers,.
2. Identification and validation of drug targets unique to paediatric cancers for therapeutic
exploitation.
3. Demonstration of proof of concept through mechanistic hypothesis-testing Phase I/II
trials of novel agents by establishing a clinical trials network with critical mass (numbers
of investigator centres and patients) and access to contemporary technologies.
4. Improve information access and ethical aspects of paediatric clinical research for lifethreatening diseases. Specifically, such policies should strive to:
•
Provide fair and equal information access for parents and patients across Europe on
clinical research and updated new therapies via internet-based dissemination such
as professional sites, Orphanet or other means of communication.
aa
see http://www.itcc-consortium.org/ for full details of faculty and ongoing projects & partnerships
166
•
Improve information quality within each trial through guidelines and parents
participation in trial design.
•
Respond to cultural and ethical differences in member states and associate
candidate countries by proposing guidelines and solutions to policy makers and
institutional entities.
5. Training for new clinical investigator centres which aim to join paediatric drug
development for young scientists and physicians, for all member states and associate
candidate countries.
[V] SWOT analysis
The faculty identified a number of general issues pertinent to public cancer drug
development (Table 5.1).
167
Table 5.1
Strengths, weaknesses, opportunities and threats for public cancer drug
development
Strengths
Innovative studies of leading edge •
NME with low commercial potential
at time of invention.
Weaknesses
Complex
multi-funder,
multiinstitutional
partnerships,
contracts and funding.
•
Broad focus on all possible •
indications
(incl.
paediatric
settings) not just ‘blockbuster’
cancers.
•
High quality peer review and follow
•
on support.
Limitations
on
advanced
technologies
(although
many
stressed this was now improving
due to national investment and new
public-private partnerships)
•
•
•
•
•
•
Commitment to support ‘tributary’
research during projects, not just •
main hypothesis. Flexibility in
being able to pursue additional
avenues.
Insufficient expertise in key areas
(QA/QC, project managers, GMP)
Problems with knowledge base in
particular
areas
of
drug
development leading to low quality
go / no-go decisions
Large intellectual network for •
developing NME and associated
biomarkers.
Complex arrangements coupled to
under-resourced,
increasing
timelines
Opportunities
Many research funders / host •
institutions have now made this
area a strategic priority (incl. the
EU IMI although many felt its
relative lack of funding and
•
direction was a weakness not an
opportunity)
Threats
Major regulatory issues (variable
response) with emphasis by some
faculty on (continued) acceptability
issues of rodent-only toxicology.
Huge expansion in new targets and
an increasing number of NME from
•
the private sector, providing major
opportunities
for
advancing
outcomes
•
More understanding of the need for
biomarker co-development to help
make the case for parallel
translational funding with cancer
•
drug development projects.
Funding is non-sustainable or a
change in strategic priorities by
federal and / or philanthropic
funders
Process too complex, slow and
expensive for public sector (or
partnership) to absorb.
Failure to develop new publicprivate models or to bridge the gap
between private versus public
investigators
Competitive
disadvantages
(protocols developed with public
intellectual input but then run in a
third country)
Source: The authors.
168
5.3.2. Results of the survey of European and USA key opinion leaders
Response rate of the questionnaire was 70.5% with 79 responses, acceptable for survey
research. Characteristics of faculty responders to the questionnaire sent out to the senior
cancer drug development faculty were analysed (Table 5.2). Apart from the sex ratio and
age range, the sample was reasonably balanced in terms of professional status, geographic
locality (by region, i.e. Europe or the USA) and area of interest.
Many of the key issues surveyed could not be sub-analyse the response distribution,
however, where clear statistical differences in responses were found are shown graphically
with the vertical axis representing number of respondents (Figures 5.1-5.16).
Table 5.2
Demographic characteristics of responses to drug development questionnaire
Sex:
Male
Female
Age Range:20-35
36-50
50+
Profession: Clinical
Non-Clinical
Country: UK
Netherlands
Germany
France
Spain
Italy
Canada
(Europe)
USA
Not Country Given
Area of Research Interest: NCE
Biologicals
Both
Not Identified
n (total =79)
71
8
6
29
44
43
36
16
5
4
3
1
3
3
(35)
39
5
39
31
6
3
Source: The authors.
169
%
90
10
8
37
55
54
46
20
6
5
4
1
4
4
(44)
50
6
49
39
8
4
[I] Investment in cancer drug development
Policies surrounding funding of cancer research are absolutely critical to the public effort
and to PPP. To quantify the views of the faculty, we asked three key questions pertaining to
the public-private role(s) in funding drug development research:
•
Is private sector support for drug development essential?
•
Is the current level of national public sector investment adequate?
•
Does the public sector have a limited role in cancer drug development?
Results were quite clear that private sector support for drug development was essential
(Figure 5.1), as shown by the number of respondents agreeing or agreeing strongly with the
question.
Figure 5.1
“Is private sector support for drug development essential?”
50
45
40
35
30
25
20
15
10
5
0
-5
-4
-3
-2
-1
0
1
2
3
4
5
Likert Scale
While there was strong view that private sector support was essential, there was a clear
division between USA and Canadian versus European views regarding adequacy of public
funding at national levels, with the former expressing insufficient funding (Figure 5.2). This is
at odds with the findings that public funding systems, particularly in the USA, have well
funded programmes of support for both pre-clinical and clinical cancer drug development.
Clearly the perception is there is ‘not enough for the job at hand’. Some commentators
questioned the role of public funding to support cancer drug development, however, from a
170
key opinion leader perspective (and in line with the pre-survey interviews), they strongly
disagree that the public role is only ‘limited’ (Figure 5.3).
Figure 5.2
“Is the current level of national public sector investment adequate?”
40
35
30
25
Europe
20
USA & Canada
15
10
5
0
-5
-4
-3
-2
-1
0
1
2
3
4
5
Likert Scale
Figure 5.3
“Does the public sector have a limited role in cancer drug development?”
60
50
40
30
20
10
0
-5
-4
-3
-2
-1
0
Likert Scale
171
1
2
3
4
5
[II] Environment for cancer drug discovery and development
The environment for drug discovery research was identified as critical to success during
the interview phase. While discussion within the pharmaceutical industry has tended to
oscillate between the ‘science problem’ and stronger management and productivity (cost,
speed, and decision making), for the public sector the concerns have been much broader,
even generic.10 In part, this lies with the fact that public sector drug development activity is
a far more networked, organic structure with multiple sovereign parties and complicated
funding models (‘source to sink’). A further factor underlying this cultural difference, a view
that came across strongly in the interviews, is that the public sector had much longer
strategic planning time-lines. Typically, ‘programmatic’ cycles of five-plus years were
presented, rather than shorter time-frames reflected by the ‘project’ approach taken by
industry.
Faculty considered intellectual environment and sufficient infrastructure support to be
the two most critical aspects for success in their drug development enterprises (Figure 5.4).
Technology transfer support and formal industry links, while generally agreed as useful,
were not seen major issues. Our data, as well as other findings from this work, strongly
suggest in cancer drug development a ‘two cultures’bb situation exists where only few
individuals from either culture makes the transition between the public and private sectors.
This is a critical issue when considering PPP, one often given very little attention.
bb
The Two Cultures is the title of an influential 1959 Rede lecture by the scientist and novelist CP Snow Its
thesis was that the breakdown of communication between the "two cultures" of modern society — the
sciences and the humanities — was a major hindrance to solving the world's problems.
172
Figure 5.4
“How important is the intellectual (academic faculty) environment?”
60
50
40
Intellectual Environment
Sufficient Infrastructure
30
Tech Transfer Support
Formal Links with Industry
20
10
0
-5
-4
-3
-2
-1
0
1
2
3
4
5
Likert Scale
[III] Models of public-private partnership
To delve into these cultural issues further, we investigated key factors around
developing successful PPP working models. In this particular area the views of the cancer
drug development faculty were much more heterogeneous. The importance of R&D
alliances for industry has certainly dramatically grown over the last decade, however, most
of the policy studies and commentaries have been focused on PPP. Increasingly, PPP have
gained traction both at institutional level (greater commercial outreach by both principle
investigators in the public sector and by host institutions themselves) and supra-national
level (e.g. Innovative Medicines Initiative and the European and Developing Countries
Clinical Trials Partnership).11
We asked our faculty the following questions:
•
Are financial incentives important for PPP?
•
Should private sector support be short-term project based?
•
Should nationalisation of parts of the drug development process be considered?
•
Is the balance between private and public cancer drug development correct?
Funding is considered ‘mission critical’, however, in response to whether financial
incentives were important for PPP, faculty was split - both disagreeing and agreeing that this
was important - but with the greatest number actually disagreeing (Figure 5.5).
173
Figure 5.5
“Are financial incentives important for public-private partnerships?”
20
18
16
14
12
10
8
6
4
2
0
-5
-4
-3
-2
-1
0
1
2
3
4
5
Likert Scale
During interviews, many of the faculty argued both for the role of the private sector in
PPP to be principally project focused, but some also suggested the model needed to evolve
with greater long term ‘infrastructure’ commitments by industry (Figure 5.6).
Figure 5.6
“Should private sector support be short term project based?”
35
30
25
20
15
10
5
0
-5
-4
-3
-2
-1
0
1
Likert Scale
174
2
3
4
5
A controversial area arising during interviews was regarding balance between the
private and public sectors (Figure 5.7). Some of those interviewed suggested that
commercial inclusion was detrimental to rational cancer drug development and potentially
stifled innovation. In these interviews, the solution tended to focus on greater public sector
(particularly governmental) involvement in supporting cancer drug development.
Discussions were complicated by numerous drivers for these views, including the need to
develop drugs for super-orphan indications and previous histories of difficult working
relations with industry. Our enquiry whether cancer drug development should receive
greater public support found clear geographic differences in responses.
Whereas European based faculty were far more neutral / modestly disagreeing with this
proposal, responders from the USA and Canada clearly felt greater public control was
needed (Figure 5.8). Although we expected this pattern to be replicated in the following
enquiry of current public-private balance correctness, we found a wide spread of responses
across the spectrum with a non-significant tendency for the USA and Canada to disagree.
Figure 5.7
“Should nationalisation of parts of the drug development process be
20
18
16
14
12
Europe
10
USA and Canada
8
6
4
2
0
-5
-4
-3
-2
-1
0
1
2
3
Likert Scale
considered?”
175
4
5
Figure 5.8
“Is the balance between private and public cancer drug development correct?”
14
12
10
8
6
4
2
0
-5
-4
-3
-2
-1
0
1
2
3
4
5
Likert Scale
Our findings suggest there is still considerable disagreement within the public sector
cancer drug development community as to ideal ‘balance’ between private and public
sector partnerships. The opportunity to investigate new models and re-frame PPP is clearly
needed. Policy has tended to focus on pharmaceutical-biotech alliances, particularly
surrounding ‘fallen angels’, as well as partnered and perceived niche products,12 however,
the importance of developing true PPP to improve innovation (knowledge enrichment, spin
off markers) and productivity is a largely unexplored area.
[IV] Key policy areas for ‘Success’ in cancer drug development
What are the key areas for new policy development over the next decade to improve
innovation in cancer drug discovery and development? One of the most important areas,
particularly in Europe since the introduction of the ‘Clinical Trials’ Directive, is the regulatory
environment. The following questions were explored:
•
Is the regulatory environment a key area for success?
•
How important are reimbursement policies of new cancer drugs to future success?
•
How important are supra-national funding initiatives?
•
How important are national funding policies from research funding organisations?
•
Is institutional support important for success in cancer drug discovery?
•
Are technology transfer and / or incentive schemes important policy areas?
176
With regards to regulatory environment as a key to success, we found substantial splits
between the USA, Canada, the Netherlands and the UK versus continental Europe (Figure
5.9). This may be partially explained by some European countries greater sympathy in
including the ‘Clinical Trials’ Directive into national legislation. However, it is clear that for
both public and private sector cancer drug development investigators this remains a hugely
serious issue.
Reimbursement of new drugs was raised by many of the faculty as a key policy issue
(Figure 5.10), and expressed during interviews that if countries or regions failed in their
reimbursement policies, then public sector alliances would be damaged. Perhaps
unsurprisingly, American faculty were relatively neutral compared with European. The
largest positive responses came from the UK, suggesting it has become an over-dominant
public policy issue skewing the focus away from other equally important factors.
Figure 5.9
“Is the regulatory environment a key area for success?”
30
25
20
Rest of Europe
15
USA, Canada, NL, UK
10
5
0
-5
-4
-3
-2
-1
0
1
Likert Scale
177
2
3
4
5
Figure 5.10
“How important are policies around the reimbursement of new cancer drugs
to future success?”
20
18
16
14
12
Europe & Canada
10
USA
8
6
4
2
0
-5
-4
-3
-2
-1
0
1
2
3
4
5
Likert Scale
Returning to the importance (or not) of public investment policies in cancer drug
development, faulty were clear that both supra-national and national policies were
essential, with a clearer consensus in the latter case (Figures 5.11, 5.12).
Figure 5.11
“How important are supra-national funding initiatives?”
40
35
30
25
20
15
10
5
0
-5
-4
-3
-2
-1
0
Likert Scale
178
1
2
3
4
5
Figure 5.12
“How important are national funding policies from research funding
60
50
40
30
20
10
0
-5
-4
-3
-2
-1
0
1
2
3
4
5
Likert Scale
organisations?”
Since the EDCTP, publication of PPP in neglected diseases report,13 and global initiatives
of GAVI and GFATM, it has become widely accepted that public funding is essential to drive
innovation mainly due to the lack of commercial viability found by orphan diseases.
However, the ‘orphanisation’ of many common cancers through molecular sub-stratification
creates the same problem of commercial viability for developing innovative cancer
medicines against rarer indications. Indeed, when one considers the rare adult cancers and
paediatric oncology, such an environment already exists.
The key environment for public sector drug development research lies within
investigators’ host institutions. While the USA has a long history of major federal support for
comprehensive cancer centres,14 Europe has lagged behind, although recent initiatives seek
to reverse this trend (i.e. cancer centre accreditation by OECI15 , Network of Core
Institutions Initiative by EORTC). Increasingly both host institutions and research funding
organisations are offering technology transfer support.
While institutional level support and organisation were seen as critical policy areas,
faculty were split on the relative importance of technology transfer support (Figures 5.13,
5.14). This may reflect a lack of knowledge or reflect stifling versus promotion of true
innovation, as exclaimed by many American faculty with the example of the Bayh-Dole
179
Act16. A similar view was expressed by a UK Royal Society report viewing IPR as a double
edged sword, both promoting invention and exploitation as well as limiting the free flow of
ideas and information.17
Figure 5.13
“Is institutional support important for success in cancer drug discovery?”
35
30
25
20
15
10
5
0
-5
-4
-3
-2
-1
0
1
2
3
4
5
Likert Scale
Figure 5.14
“Are technology transfer and / or incentive schemes important policy areas?”
25
20
15
10
5
0
-5
-4
-3
-2
-1
0
Likert Scale
180
1
2
3
4
5
[V] Cancer research and development models
Turning full circle, we return to the question on whether current PPP models or indeed
cancer drug R&D models are currently appropriate or whether new policies are needed:
•
Are new models in PPP needed?
•
Are new models for R&D in cancer drug discovery and development needed?
Responses to both these statements found major consensus that both the current R&D
models and PPP arrangements require change if cancer drug development is to be
successful in the future (Figures 5.15, 5.16). During interviews, various solutions and options
were offered including major supra-national re-organisations, harmonisations and key
paradigm changes in the science approach. The core solutions are discussed below.
Figure 5.15
“Are new models in PPP are needed?”
45
40
35
30
25
20
15
10
5
0
-5
-4
-3
-2
-1
0
Likert Scale
181
1
2
3
4
5
Figure 5.16
“New models for R&D in cancer drug discovery and development are needed”
50
45
40
35
30
25
20
15
10
5
0
-5
-4
-3
-2
-1
0
1
2
3
4
5
Likert Scale
5.4. Discussion and policy implications
This section empirically examines the interaction, relationships and perceptions around
cancer drug discovery and development between the public and private sector by focusing
on the former community. The weaving of both quantitative data from the questionnaire
and qualitative data from interviews has provided one of the first major evidence-based
studies of public sector cancer drug development. Ideally we would have had more
responders from non-English speaking countries, particularly those countries increasingly
engaged in cancer drug development, such as India, Japan and China. In light of our high
response rates and commonality of views on many policy issues, our results are likely to be
widely applicable and may serve as a benchmark for future high resolution studies.
5.4.1. Public-Private Partnership Models
Models of PPP are currently a key policy area. In the last two decades there has been a
proliferation PPP internationally in health research, primarily developing and transitional
countries within Group I diseases (infections, perinatal mortality, etc). Whilst the notion of
182
PPP is not new with such models existing as early as 1969,cc there have been rapid changes
in conceptual and operational approaches. These changes have often been driven by
perceived or real deficiencies in public health, often including UN sponsorship. Definitions of
PPP have varied but with common flavour - “a collaborative relationship between entities to
work toward shared objectives through a mutually agreed division of labour”18 or “…a group
of allies sharing the gaols, efforts and rewards of a joint undertaking”.19
Despite the globalisation of the cancer burden, surprisingly little thought has been given
to the nature of international PPP in any domain of cancer research with most of the focus
being placed upon carcinogen control and national cancer control programmes. Indeed,
such a deficiency is apparent across all aspects of non-communicable diseases. In the
domain of cancer drug development, our data from key opinion leaders clearly shows both
public and private sectors are neccessary. While there might be disagreement over the
current and ideal balance of public and private sector, what is absolutely clear is new
models are urgently needed. An integral part of this finding was the expression by that the
overall R&D model for cancer drug development needs changing to reduce attrition rates,
increase the rate and sophistication of parallel biomarker development, and to process the
vast numbers of combination regimens and indications for the next generation of cancer
drugs. Some of our data suggest that in certain geographic regions the appetite for greater
public sector involvement in key cancer drug discovery areas is substantial. In particular, the
key PPP areas for policy development were:
•
Strong institutional support and dedicated funding from public research
organisations.
•
New models increasing freedom-to-operate for important translational leads within
specific projects, via improving support, light touch governance and a substantial
decreasing administrative bureaucracy (nationally legislative, private-contractual,
public-contractual).
•
Partnerships supporting trans-national co-operation and collaboration focused on
key cancers, including ‘orphans’ and not commercially attractive cancer.
cc
Pearson Commission on International Development
183
The need for these new policy approaches was tempered by expressions that these
partnerships should be in the ‘public good’, subject to high quality peer review and fully and
publicly disclosable upon completion. Clear organisational policies, guidelines, selection of
partners and governance was seen as essential to ensure an appropriate balance of public
funding to compete priorities and transparent probity in the conduct of drug development
research. Work in other areas of PPP could easily be applied to protect the legitimacy and
integrity of such models.20
5.4.2. Investing in Cancer Drug Development
Public funding remains a key areas for cancer drug development. Whilst there was
acknowledgement that budgetary concerns were putting increasing pressure on both
national and philanthropic funding, the faculty expressed a need for debate around the
issue of the public funding of cancer drug development research (and in cancer research per
se). Both in the USA and Europe, federal funders were considered relatively slow to support
public sector involvement in cancer drug discovery, and although there was clear
recognition that supra-national initiatives were needed, there was disagreement about how
this funding should flow. For example, the European faculty agreeed with the identified
bottlenecks that had been identified,21 however, remained broadly neutral on whether the
IMI was sufficiently resourced to achieve such ambitious aims. Indeed part of the problem
identified was the substitutional nature of this funding in many member states. Crucially,
and a major difference commercially, faculty viewed the role of public funding as to provide
long-term stable infrastructural funding with arms-length governance to allow creative
partnerships. Key multi-national, multi-group initiatives aimed at specific barriers in cancer
drug development were further considered important areas for new PPP funding initiatives.
However, most faculty did not see financial incentives as key drivers in such public-private
partnerships, instead commenting that patient outcomes and benefits were the most critical
test of drug development irrespective of commercial viability.
Previous research has supported the importance of public sector investment in basic
sciences,22 as well as correlated between federal funding and privately funded research,23
however, the importance of public sector investment for drug development research for
184
specific therapeutic area has not been extensively examined. Our findings strongly support
the need for the public sector investment across all areas of cancer research, including drug
discovery and development. It is clear there is not a simple linear relationship between the
public and private sector investment in drug development research, where the public sector
performs the more ‘basic’ aspects and the private sector exploits this. Rather, there is a
more complex interplay along the entire development pathway continuing into post
marketing. One critical point made by faculty was a need for both the private sector and
public policymakers to appreciate cancer drug development extends past Phase IV, and not
considered fait accompli once marketing authorization is given. Key policy issues were:
•
Requirement for specific federal programmes aimed at critical scientific hurdles and
orphan areas.
•
National, and less so supra-national policies, directed at public sectors are
considered essential. Currently many countries do not have sufficient public sector
support.
•
Investment in dedicated training cancer drug development programmes for both
clinical and non-clinical faculty.
5.4.3. Environment for cancer drug development
Our findings indicate intellectual environment (“trained drug development faculty
embedded in centres with sufficient critical mass”) and infrastructure provisions were
considered the most important areas for institutional and national policies. Many faculty
commented the time had come to be more rational about which major technologies centres
should invest is and which centres they should ‘have’ via external strategic alliances. Many
comments focused on the role of federal funding to provide dedicated facilities for clinical
development as well as key clinical technologies. While public funding is recognised as
essential for proof-of-concept work feeding into downstream product development,
national RFO’s and institutions have a broader role in providing dedicated clinical facilities
185
plus specific facilities to support development work in such areas as novel biologicalsdd. Both
Europe and the USA have major supra-national initiatives aimed at drug development (IMI
and Critical Path Initiative), however, faculty saw these as lesser priorities than ensuring
sound institutional level and national level policies.
A number of countries clearly identified over-regulation and reimbursement of new
cancer drugs as critical policy issues. In the case of regulatory impact, there is a clear
difference in opinion between the countries that have been subjected to the full force of
multiple regulations and those, it appears that have not been. Issues of over-regulation
continue to overshadow all aspects of public sector clinical cancer research, remaining one
of the greatest future threats for both public and private sectors. Regarding government
intervention, some faculty pointed to the additional impact (both negative and positive) of
government legislation (in the case of Europe this mostly focused on the impact of
Directives and Regulations). While agreeing that a balanced approach25 was essential, the
key policy issue focused on the interface between policy-makers and the public sector drug
development community, with a clear view that in the battle for the legislative ‘hearts and
minds’, the private sector had disproportionate access to and influence on policy-makers.
In summary, this paper is a first examination of public sector opinions of cancer drug
development. Results show strong opinions for the need of PPP, although conflict on the
degree of regulation and public-private balance. What is undisputed, is the need for reexamination of cancer R&D models in order to increase efficiency in cancer drug
development and ultimately affecting cancer outcomes.
New policy approaches are
needed, including greater transnational cooperation, support of translational research and
degree of institutional involvement.
Funding for this new approach and cancer R&D
remains problematic, with no clear resolution on best balance of short- versus long-term
planning and degree of bureaucracy.
Investment in intellectual environment remains
important, in addition to examination of regulation bottlenecks. Ultimately, the goal is best
cancer outcomes with cooperation the key to improving cancer survival.
dd
E.g. NCI/NIH Developmental Therapeutics Programme (http://dtp.nci.nih.gov/) and the Experimental
Cance Medicine Network (http://www.ecmcnetwork.org.uk/)
186
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188
6. SUPPORTING AND ENABLING INNOVATION IN
ONCOLOGY: ISSUES IN PUBLIC POLICY
6.1. Background and Objectives
This chapter addresses the question of value of pharmaceutical innovation,
particularly in oncology, from a societal perspective and endeavors to address the
following questions: first, how do we derive value from innovation; second, is
medical innovation in health care worthwhile; third, what approaches are in place to
assess the value of (pharmaceutical) innovation, particularly in European countries;
and, fourth, from a public policy perspective, how do we provide incentives for
pharmaceutical innovation particularly in oncology.
Section 2 outlines the methodology employed in this chapter. Section 3 critically
appraises the contribution of pharmaceutical innovation to health, health care and
well being by drawing on international literature. Section 4 debates whether health
and pharmaceutical innovation have been worthwhile from a societal perspective,
then discussing evidence on clinical and socio-economic benefit. Section 5 outlines
the different approaches to valuing pharmaceutical innovation in oncology and in
Europe in particular, and focuses on clinical effectiveness, rate of return regulation
and value based pricing. Section 6 discusses available incentives to drive the process
of therapeutic innovation forward. Finally, Section 7 draws the main conclusions.
189
6.2. Data and methods
Both primary and secondary data sources were used to provide the evidence
base for this chapter.31 The geographical focus of analysis is the European Union,
although evidence is drawn from elsewhere, particularly the USA.
Secondary data was acquired by meta-analysis of existing literature on
innovation benefits using sources collated from academic databases (primarily
Medline and IBSS) as well as governmental bodies, non-governmental organisations
and industry publications. Two phrases entered into search engines: ‘value of
innovation’ and ‘pharmaceutical innovation’, originally producing 1,083 and 1,008
results respectively and subsequently filtered for inclusion and resulted in 60
relevant studies.
Primary data were acquired by means of a questionnaire survey in 15 EU
countries (UK, Germany, France, Italy, Spain, Netherlands, Sweden, Czech Republic,
Switzerland, Denmark, Poland, Slovakia, Greece, Finland and Portugal). The survey
asked experts in each country to reflect on national policies to assess the value of
pharmaceutical innovation, circumstances under which price premia are awarded to
new medical technologies, and existence of bias or preference towards certain types
of new treatments (e.g. oncology agents) versus others (e.g. new anti-retroviral
treatments). The survey tool also distinguished between breakthrough and
incremental innovation. Experts included academics and a range of decision makers.
31
This chapter builds on the methods outlined in: Kanavos P, Li G, Vandoros S. (2008). The Value
of Pharmaceutical Innovation: Perspectives and Outlook, Paper submitted to LIF LSE Health, mimeo,
December. The chapter extends and updates the evidence in that paper to 2009.
190
6.3. Contribution of pharmaceutical innovation to health and
well being
6.3.1. What is innovation?
The term innovation implies a new way of doing something. It may refer to
incremental, radical, and revolutionary changes in thinking, products, processes or
organizations.1 The objective of innovation is positive change, to make someone or
something better. In economics the change must increase value, customer value or
producer value. Innovation leading to increased productivity is the fundamental
source of increasing wealth in an economy.
Similar to the above generic definition of innovation is applied to medical and
pharmaceutical innovation, and comprises both radical (breakthrough) and
incremental innovation. Health care markets often treat breakthrough innovation
differently from incremental innovation, with often processes in place to enable
stakeholders to differentiate between these two innovation types. Some systems
attempt to adopt a specific framework in order to recognise different types of
medicines based on their innovative potential. For example, the US Food and Drug
Administration (FDA) distinguishes between priority review and standard review
drugs. Standard review “is applied to a drug that offers at most, only minor
improvement over existing marketed therapies”, whereas priority review is applied
to “drugs that offer major advances in treatment, or provide a treatment where no
adequate therapy exists”. Although some studies have attempted to quantify the
differential effects of standard versus priority review drugs on health outcomes, only
tentatively suggesting a significant effect, this area requires more research to
substantiate these claims.
One issue particularly pertinent is incorporation of post-marketing information of
drug safety or efficacy and the method for price premium adjustment, if at all, to
reflect this new information. This is important given the current debate about exante versus ex-post value assessment (and therefore pricing) in some policy settings,
notably the UK, and perhaps Sweden.
191
6.3.2. Impact of pharmaceutical innovation on health
Over the past 25 years, medical and pharmaceutical innovations, both
breakthrough and incremental, have transformed treatment of severe illnesses such
as cancer and rheumatoid arthritis, and dramatically improving patients’ lives.
Achieving even incremental innovation requires significant investment and
commitment in resources and therefore perceived as a challenge for healthcare
systems. Critics typically site (rising) pharmaceutical spending as a major contributor
to spiraling healthcare costs, suggesting pricing practices and pharmaceutical /
biotechnology industry profits are largely to blame for healthcare budget crises in
many countries. Others believe the opposite to be true - rather than being the
problem, pharmaceutical innovation on the part of the overall pharmaceutical /
biotechnology industry has added significant value to patients, to the economy and
to the larger society. In a recent study on the relative importance of medical
innovations, clinicians were asked to identify and rank the health care technologies
they consider most valuable to themselves and their patients. Pharmaceutical
interventions, such as ACE inhibitors, statins, PPIs, H2 blockers and inhaled steroids,
were all ranked very highly on that list reflecting the therapeutic benefit they
deliver.2
Indeed, the evidence on the value of medical and pharmaceutical innovation and
its contribution to health, productivity and return on investment (ROI) is substantial
and growing. For example, treatments for heart attacks deliver a $7 return on each
$1 of invested in new therapies, such as thrombolytic medicines, stents, and longterm drug therapies (1984-1998).3 Improved treatments for low birth-weight infants
show a $6 return for each $1 incremental investment in new therapies, including
special ventilators and artificial surfactants (1950-1990).3
Specific classes of drugs, such as statins, have proven to deliver extraordinary
value
4
in a number of ways, both for primary and secondary heart disease
prevention. Early statin initiation following an acute heart attack reduces the risk of
fatal heart disease or a recurrent heart attack by 24%; every dollar spent on statin
therapy in heart attack survivors (versus usual care) has produced health gains
valued as high as $9.44. In Type II diabetes patients, statin therapy to lower
192
cholesterol also decreases the risk of coronary events by 25%; every additional dollar
spent on statin therapy in Type II diabetics with high cholesterol produces health
gains valued at $3. Beta blockers are another example of high positive return on
investment, as treatment of heart attack patients with beta blockers show a 35 to 1
return (MEDTAP 2004).4 In cardiovascular disease, GDP gains resulting from
increased public/charitable medical research in the UK deliver an additional rate of
return ranging from 20-67%, while the internal rate of return from the value of UK
net health gains was over 9%.5
Drug innovation has also transformed the treatment of grievous illnesses,
including cancer where significant value has been delivered both at societal and
patient levels with the promise of future progress. Research estimates that
innovative cancer drugs have increased the 1-year crude cancer survival rate from
69.4% to 76.1%, the 5-year rate from 45.5% to 51.3% and the 10-year rate from
34.2% to 38.1% (1975-1995).6 These increases accounted for 50-60% of the gains in
age-adjusted survival rates during the first 6 years after diagnosis, added more than
one year of life to patients diagnosed with cancer in 1995 and increased the life
expectancy of the entire U.S. population by 0.4 years (since lifetime risk of being
diagnosed with cancer is roughly 40%).6 Further research suggests the value to the
patient of a cancer-free life year is actually closer to about $300,000, well above the
typical $30,000-75,000 per QALY values used as thresholds in health economic
evaluations. 7, 8
If society continues to fund further research in cancer therapy, it is likely greater
rewards could be expected. Recent studies suggest a cure for cancer might be worth
$47 trillion,9 while a 1% reduction in cancer mortality worth $500 billion.9, 11
Despite increasing evidence on the impact of pharmaceutical innovation in
society, there is concern the value of pharmaceutical innovation may not be fully
recognized; there are gaps in measurement, value affected by pricing, or / and
reimbursement policies. Metrics, standards and tools to assess drug value are often
incomplete and inadequate, as they typically measure and assign a value to life years
saved with some estimate of quality adjustment and direct cost offsets, but fail to
addiitonally measure a number of important parameters of interest, such as:
193
•
Value to society, not only from the view point of the healthcare system, but
on overall economic productivity;
•
Value to the patient, the caregiver and also the physician; and
•
Value over time, of the value achieved during the initial treatment period and
also of the benefits realized over the duration of the patient’s life (e.g.
avoiding costs of future treatments).
Even when a more comprehensive set of metrics is considered, payers and
insurers have frequently made explicit decisions to exclude some sources of value
(e.g. impact on productivity) from their assessments of the relevant technologies or
interventions.
Assessments of value do not take into account the fact that patent protection
only allows pharmaceutical and/or biotechnology companies to realize the benefits
of their innovation for a fixed period, while society enjoys the same benefits in
perpetuity. For example, the manufacturer of Prozac enjoyed the financial benefits
of this innovation during its effective patent term post launch, but millions of
patients continue to enjoy these benefits today at much reduced (generic) prices. In
sum, if all the benefits of drug innovation were appropriately quantified and
considered, the value of such innovation over the past three decades would
potentially be even larger than initially estimated.
6.4. Is health care and pharmaceutical innovation worthwhile?
This section discusses the societal benefits of innovation illustrating how clinical
benefits, such as faster recovery (partial or total), higher tolerability, higher survival
rate or life expectancy, are more relevant to some therapeutic areas than others, but
the socioeconomic benefits gained (e.g. higher productivity) have much in common.
194
6.4.1. Therapeutic/clinical benefits
[I] Life expectancy and survival
One of the benefits of pharmaceutical innovation across an ever-increasing range
of therapeutic areas is the increased likelihood of an efficacious therapy for any
given disease existing which ultimately reduces morbidity and the probability of
mortality. Numerous studies have attempted to model the decline in mortality rates
for a variety of clinical conditions (e.g. coronary heart disease, diabetes, colorectal
cancer etc.) attributable to the introduction of new pharmaceutical therapies over
the last 50 years.
Although this link between pharmaceutical innovation and increased life
expectancy might seem obvious, econometric analyses have nonetheless been
carried out to estimate the quantitative impact of the approval of new drugs on
mortality rates from HIV and rare diseases.12 Though the results of regression
analyses support the hypothesis that increased availability of new drugs is associated
with a decline in mortality rates, the mechanism by which this might occur is unclear.
Some of these clinical benefits potentially contributing to increased life
expectancy/decreased mortality are disaggregated in the following sections.
[II] Higher probability of faster or full recovery, and preventing re-emergence
The link between improved therapeutic/clinical benefits and the development of
innovative pharmaceuticals is often preceded by a progression in knowledge of
disease aetiology. Chronic myeloid leukaemia (CML) is one example where
understanding of the molecular basis at a genetic level led to rational design of a
successful targeted therapy. Aided by well-established diagnostic procedures and
prognostic factors, the development of Imatinib, a tyrosine kinase inhibitor which
helps slow cancer cell proliferation, significantly improved the chances of remission
for sufferers of CML, such that 87% of patients now achieve remission. 13
If new treatments show higher probability of faster/full recovery or a higher
probability of preventing re-emergence, then payers are typically inclined to award
price premia over existing therapies across surveyed countries.
195
[III] Slowing disease progression
In an age where chronic diseases are becoming increasingly prevalent, slowing
disease progression is of significant importance. Diabetes, affecting 1.4 million
people in the UK14 and several million across Europe, is associated with debilitating
long-term clinical complications, including retinopathy, peripheral neuropathy,
cardiovascular disease, hypertension and nephropathy.
Innovation has affected diabetes therapy through the discovery of glitazones, a
group of molecules that increase sensitivity to insulin therapy, revolutionary in noninsulin dependant diabetes. In an economic evaluation in the UK NHS setting, Beale
et al. (2006) found rosiglitazone combination therapy combined with metformin
resulted in better glycaemic control than traditional treatment consisting of
metformin and sulphonylurea.15 Patients on rosiglitazone combination therapy
enjoyed a greater life expectancy with an average 123 life years gained per 1000
obese patients. As this treatment delays the onset of insulin therapy, it also results in
significant improvement in patients’ quality of life. The reaction of payers to a value
proposition promising to slow disease progression and delay or exclude more
invasive therapy is also very positive in principle.
[IV] Less severe side-effects
Adverse side-effects can decrease treatment compliance and in the long-term
result in higher costs - unused and wasted medication in the UK NHS is currently
valued at £100 million annually.16 This is an important issue in psychiatry where
patients’ suitability for community versus institutional care is conditional on
medication adherence. Selective serotonin re-uptake inhibitors (SSRIs) used in
depression treatments have fewer side effects than traditional tricyclic
antidepressants (TCAs). Several studies have shown, despite the price premium
awarded to SSRIs, treatment substitutions could be made with virtually no change in
overall costs due to reduced readmissions.
17
However, a review assessing the
economic benefits of TCAs and SSRIs found although direct medical costs were lower
with SSRIs administration, it was difficult to make a definitive evaluation of the
196
overall socio-economic impact of prescribing SSRIs vs TCAs due to the omission of
possible confounding variables.18
The importance of increasing tolerability is particularly relevant to CNS
therapeutics as side effects often have behavioural consequences. For example,
third-generation antihistamines developed from active ingredients of secondgeneration agents, retain the activity of the parent compound but with improved
tolerability and pharmacokinetics yet fewer side effects of reduced drowsiness and
improved safety.
[V] Broader, easier dosing and administration to improve compliance and
efficacy
One area in which such incremental innovation occurs is in the development of
new drug delivery methods. Clinical benefits of innovative drug delivery forms
include a simpler dosing regimen, improved compliance, improved pharmacokinetic
profile, increased safety and fewer adverse side-effects. 19
To improve compliance, the dosing regimen can be simplified to involve fewer,
higher dosage administrations. Methylphenidate, prescribed for Attention Deficit
Disorder, can now be administered twice daily, resulting in increased efficacy of the
drug while reducing the amount of disruption in a child’s school routine.
[VI] Quality of life: Greater physical, psychological and social self-sustainability
In some cases, the treatment itself may cause a decrease in quality of life. For
example, intravenous chemotherapy treatment is toxic and unpleasant to
administer. In the majority of cases improvements in quality of life are recorded.
Treatment for multiple myeloma has benefited from recent developments in the
production of an oral form of immuno-modulatory drugs such as thalidomide
benefiting from lower toxicity and increased patient quality of life.
20
Another
example of improvement in quality of life is for mental illnesses where discoveries in
neuropharmacology have enabled patients to participate in their family and
community while receiving treatment.
197
It is often difficult, however, to assess of individual quality of life. This is
particularly true with regards to mental health patients as their subjective opinion of
their quality of life often diverges from objective bystanders such as caregivers.
Consequently, effort in developing new surveys have been made to capture a more
accurate quality of life assesment to be used for treatment decision making.
6.4.2. Socio-economic benefits
[I] Reduced total costs of treatment and non-drug spending
One of the primary socio-economic benefits potentially accruing to the payer
(and society) as a result of innovative therapies is a net reduction in total treatment
costs, for example as a result of increased compliance leading to increased efficacy.
Kleinke (2001) suggested six ‘value propositions’ to categorise innovative
pharmaceuticals, depending how costs and benefits of the drug are realised with
respect to time and the size of the population (Table 6.1). 21
198
Table 6.1
The six economic categories for innovative medicines
Kleinke's 6 'Value Propositions'
Fast Pays
Expensive new drugs with lower short-term health care costs. A bargain for
payers and society compared with the cost of the services and chronic diseases
that they delay, manage or prevent e.g. anticoagulant for stroke
Slow Pays
New drugs which decrease medical costs only after several years. Often they
may form part of a disease management programme, e.g. diabetes medication
New drugs which decrease overall medical costs for only a narrow subset of the
population and do not offset their overall medical costs. These drugs often are
prescribed for clinical problems that are imprecise, difficult to diagnose or have
a high preval
New drugs which increase medical costs but simultaneoulsly decrease nonDiffuse-pays
medical costs. E.g. Vaccine for common flu. Employers may be keen to provide
this for employees
The 'pay-me-laters' New drugs that lower short-term health care costs but increase long-term costs.
They improve health status, short-term costs and overall life expectancy whilst
resulting in higher costs in the long-term. E.g. cystic fibrosis treatment
Narrow Pays
The 'no-pays'
New drugs which do not save money - they improve people's lives, often
labelled as "recrea-ceuticals" e.g. Viagra, drugs for mild obesity
21
Source: Adapted from Kleinke, 2001.
199
In particular, it has been suggested newer drugs prescriptions appear to reduce
overall total non-drug medical spending. Evidence gathered from the 1996 U.S.
Medical Expenditure Panel Survey (MEPS) found a positive correlation between the
age of a drug and the health care spending patients consuming the drug. 22 The study
found newer pharmaceutical therapies reduced all types of non-drug health care
spending, with the reduction of inpatient spending being most significant; their
model suggested that increases of $18 in prescription charges were offset by a
reduction of $71.09 in non-drug charges. In line with the notion that newer therapies
provide direct economic benefits compared to older therapies, these publications
were thought to have important implications for pharmaceutical policy.
However, this set of analyses has been criticised for not accounting whether the
medication prescription was concomitant with or post-dated the non-drug health
care costs, as this has implications for the direction of causality in the relationship
between health care costs, severity of illness and drug age. The studies were also
carried out over very limited time periods with little longitudinal data. Controlling for
these factors reduces the significance of the results of the Lichtenberg model and
brought into question its reliability.
23
Therefore, further work needs to be
undertaken in this area, particularly using longitudinal data and analysing policy
implementation effects.
[II] Costs and outcomes
Any reduced costs have to be considered alongside the change in the delivered
clinical benefits, as the relationship between cost-savings and socio-economic
benefits is far from straightforward. In this context, cohort studies from the
American Medicare system investigated patient outcomes admitted for hip fracture,
colorectal cancer treatment or myocardial infarction across states with different
levels of Medicare spending.
24
They found patients in higher-spending states
received more care, although this did not lead to significantly lower mortality rates,
better functional status or better health services satisfaction. What cannot be
concluded from this study, however, is whether reducing spending in some areas
could have a negative effect on health outcomes. Further research is needed to
200
understand the dynamics of reducing spending without adverse effecting patients,
whether this is feasible and in what therapeutic areas.
One problem with properly assessing the cost savings from new therapies is ideal
settings found in clinical trials are often not replicated in real life. To this end, Cutler
et al. (2007) carried out an empirical study modeling the effects of hypertensive
therapy over the last 40 years using data from the Framingham Heart Study and the
US national survey to estimate health outcomes in the absence of innovation in CHD
treatments. 25 Although their model had limitations including the inability to control
for lifestyle factors associated with CHD such as exercise and sodium intake, their
static analysis suggested that US$17.5 billion in costs have been avoided as a result
of decreased MI and stroke compared to annual costs of anti-hypertensive
medication at $8.8 billion, suggesting a cost-to-benefit ratio in favour of this
treatment.
Treatment costs may not always be offset by accrued savings, resulting in
government or payer making judgments about the ‘willingness to pay’ threshold.
Statin use in the UK NHS is one example, where value avoided costs statin use was
calculated at £218 million but not offset by the total statin costs estimated at £3.2
billion. Nonetheless, statins are estimated to have saved approximately 17,400 lives.
26
[III] Innovation as a driver of increased costs
Many health policy makers regard innovation, both technological and
pharmaceutical, as primary reasons for increased health care costs.3 Treatment for
indications such as myocardial infarction are now more labour, capital and
knowledge intensive than 30 years ago. Some argue although many new medical
treatments represent genuine medical advances providing novel therapeutic
opportunities for patients, there is also a tendency for inappropriate application and
over-use. For example, the US has twice as many MRI machines per capita than
Western European countries, yet arguably provides no difference in health
outcomes.27 In this context, Health Technology Assessments (HTA) play an important
role in informing decisions about appropriate rate of technology diffusion according
201
to evaluated benefits, drawbacks and cost-effectiveness of an innovative treatment,
intervention or technology.
[IV] Increased costs and R&D
It is argued that bringing an innovative pharmaceutical product to market, with
all associated clinical and socio-economic benefits, is costly and manufacturer profits
are needed to ensure cash flows for future R&D. However, closer examination of
American pharmaceutical manufacturers’ gross margins versus their R&D
expenditure in a time series analysis reveal the pharmaceutical industry behaves
consistently with a rent-seeking model, with industry R&D investments only slightly
surpassed by risk-adjusted capital costs. Evidence suggests as firms evaluate
potential profit opportunities, they increase R&D investments and may over-invest
to almost eradicate any supra-normal profit. 28
Although intense debate exists as to what amounts excessive profits, an issue
particularly relevant to the UK with a profit regulation scheme negotiated between
the NHS and the pharmaceutical industry, profits nevertheless act as powerful
incentives for innovation. Ideally, innovation could be directed at those areas where
significant social returns can be made. One suggested method to achieve this is via
the distribution of financial rewards from the health care payer to the innovator
themselves, at a value in line with the social value of the (incremental) innovation,
thereby aligning social objectives with industry objectives. 29 Although such models
face many obstacles in terms of practical implementation, they raise important
questions about the way in which the equity and efficiency objectives of both society
and the pharmaceutical industry can be achieved simultaneously.
[V] Loss of work costs and higher productivity
One important aspect health care payers may consider is the benefit accrued in
terms of lower loss of work costs and higher productivity in the work force.
Importance of such costs are demonstrated in the example of varicella (chicken pox):
from a health care payer’s perspective, routine childhood vaccination would cost $2
per case prevented, $2500 per QALY, whereas alternative calculations accounting for
additional loss of work and medical costs find $5 savings per $1 spent vaccinating. 30
202
Impaired performance is also an issue where an illness does not prevent work
attendance but nonetheless affects the individual in their workplace. For example,
the indirect costs of migraine to the employer were recently estimated to be US$12
million. 31 Older therapies such as sumatriptan have been demonstrated to be costeffective, analysis of migraine-related productivity losses in US firms suggested the
replacement of standard therapy with newer rizatriptan would result in additional
annual savings of $84 - 118 US per employee by avoiding productivity losses. 32
[VI] Preventing spread of infectious disease
Prevention of pandemics of infectious diseases, which have debilitating
economic effects from workforce productivity plus diminished quality of life, is also
an issue to considered. For example, an innovative therapy recently involved in
reimbursement decisions in several countries is the human papillomavirus (HPV)
vaccine, with demonstrated 98% efficacy against HPV16/18 infection during clinical
trials. Infection with strain HPV16/18 is associated with 97% of cervical cancer and
without screening programmes found in some countries, there would be several
thousand deaths per year from cervical cancer. In the UK alone, it is estimated an
absence of screening would lead to 5000 deaths annually from cervical cancer.
33
Benefits of this new vaccine need to be offset against its modest administration costs
to the eligible population - if administered to all females in the UK under the NHS, it
would represent an additional annual outlay of approximately £10 million for the
Department of Health. 34
[VII] Decreasing resistance
Therapy resistance results in many inefficiencies, due to wasted medications,
greater clinician attention required and effecting patient’s quality of life through
protracted suffering. Resistance is particularly an issue in antibiotic treatments.
Bacterial resistance to antibiotics can be exacerbated by using inappropriate
spectrum antibiotics, inadvertently selecting those bacteria harbouring resistance.
Developing new generations of antibiotics has been key to increasing the choice of
different treatments available, enabling physicians to select the appropriate
treatment for a given strain of bacteria. For example, fourth-generation
203
cephalosporins can target a much wider range of gram-positive and gram-negative
bacteria than their first generation counterparts, resulting in a wider range of
therapeutic uses.
6.5. Different approaches to valuing pharmaceutical innovation
in Europe
6.5.1. Valuing innovation in the context of drug reimbursement
Few would disagree that pharmaceutical innovation is worthwhile, although
many would argue not all of the features discussed in the previous sections are
weighed equally due to differences in opinion across different settings, often
dominated by individual value judgments. Indeed, the debate surrounding the value
of innovation centers not only around clinical criteria, but also socio-economic and
budgetary. This is done with a view to decide how new products should be
reimbursed and whether the decision to reimburse them meet a number of criteria.
The type of criteria applied in this context and across study countries vary (Table
6.2), and range from therapeutic assessment of cost effectiveness and budgetary
impacts to cross-country price comparisons.
204
Table 6.2
Criteria for assessing new technologies in 15 EU countries (2009)
Therapeutic benefit
Patient benefit
Cost efficacy/ cost effectiveness
Budget impact
Pharmaceutical / Innovative
characteristics
Availability of therapeutic
alternatives
Equity considerations
Public health impact
R&D
Unmet need
Price in other countries
Price of similar / comparable
products
Other
Price freedom
UK
✓
✓
✓
✓
✓
✓
✓
✓
GER
✓
✓
FRA
✓
✓
ITA
✓
✓
✓
✓
✓
SPA
✓
✓
?
✓
NL
✓
✓
✓
✓
✓
SWE
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
SWI
✓
✓
✓
DEN
✓
✓
?
FIN
✓
✓
✓
✓
CZ
✓
✓
?
✓
POR
✓
✓
✓?
✓
GRE
✓
✓
POL
✓
✓
✓
✓
SLK
✓
✓
?
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓
✓?
✓??
Notes: UK=United Kingdom; GER=Germany; FRA=France; ITA=Italy; SPA=Spain; NL=The Netherlands; SWE=Sweden; SWI=Switzerland; DEN=Denmark;
FIN=Finland; CZ=Czech Republic; POR=Portugal; GRE=Greece; POL=Poland; SLK=Slovakia;
✓?=applies in part in the case of the UK and Portugal; ✓??=applies in part in the case of France; ?= not a formal requirement to arrive at decisions, but
local expertise exists, which may feed into the decision-making process.
Source: The authors, based on responses received. The table extends the evidence presented in Kanavos, Li and Vandoros (2008).
205
All countries apply multiple criteria to inform decisions about inclusion of new products
in the reimbursement list and the rate at which a new product might be reimbursed. More
often than not, valuing an innovative new medicine becomes a function of the price the
same medicine commands in neighbouring countries.
Despite the wide range of criteria used explicitly or implicitly to inform pricing and/or
reimbursement decisions, explicit strategies used in practice to value pharmaceutical
innovation are limited. Evidence suggests that European countries apply three different
approaches to valuing pharmaceutical innovation: first, rate of return regulation which,
based on its application in the UK, includes incentives to conduct R&D. Second, assessment
of clinical / therapeutic benefit of individual technologies by ranking new treatments based
on their therapeutic potential, as is currently undertaken in France and less so in Italy. Third,
HTA to inform the relative effectiveness of new treatments. Several countries apply HTA
explicitly (UK, the Netherlands, Sweden, Switzerland, Finland, Poland), while in others HTA
plays an increasing role but not used explicitly in decision-making. All three approaches are
pursued nationally due to national management of health and pharmaceutical care budgets.
Supra-national bodies such as the EC have no competence in deciding on allocation or
spending of health care budgets, and by default have no competence in passing judgment
on methodological valuation of new technologies or treatments. The following sections
outline each of the three approaches identified and also discuss the role of European
institutions in value assessment.
6.5.2. Rate of return regulation
Rate of return regulation applies in the case of the UK, through the Pharmaceutical Price
Regulation Scheme (PPRS), which regulates the profits of pharmaceutical companies and,
indirectly through profits, the prices of medicines. The scheme has been in operation in the
UK for over 50 years and administered by the UK Department of Health.
The PPRS objectives are: first, to deliver value for money for the UK NHS by securing the
provision of safe and effective medicines at reasonable prices, and to encourage efficient
development and competitive supply of medicines; second, to encourage innovation by
promoting a strong and profitable pharmaceutical industry capable and willing to invest in
206
sustained R&D for future availability of new and improved medicines benefiting patients
and industry; third, to promote access and uptake for new medicines; and fourth, to provide
stability, sustainability and predictability to help the NHS and industry develop sustainable
financial and investment strategies. The scheme applies to branded generics, vaccines, invivo diagnostics, blood products, dialysis fluids, branded products supplied through
tendering processes on central or local contracts, and biotechnology products.
The relatively free pricing in the UK – which is, nevertheless, subject to negotiation and
moderate reduction in prices each time the scheme is re-negotiated - makes it an attractive
market for the launch of new pharmaceutical products. It also provides clear incentives for
innovation through the return on capital employed (ROCE) and R&D allowances. A thorough
assessment of the true socio-economic value of innovative pharmaceutical products in the
UK is particularly important, as the UK is a price-leader in international reference pricing.
The countries which reference prices to the UK represent approximately 25% of global
pharmaceutical markets (though not all products in each country are referenced to the
UK,).35
The scheme has been criticised on several occasions for non-transparency, capital overinvestment and for inefficiencies. The divergence between price and value was the main
focus of a Office of Fair Trading (OFT) investigation report35, calling for radical overhaul of
the scheme in favour of value-based pricing. The key argument in favour of a new approach
from the OFT perspective is that “…neither the profit nor the price controls take account of
the therapeutic value of drugs. This undermines the extent to which they can help secure
value-reflective prices for the NHS. For a scheme that sets out to deliver value for money for
the NHS and give companies the right incentives to invest, we consider this to be a
significant flaw… the UK is almost unique in the world in not taking explicit account of the
therapeutic benefits of drugs in its pricing system.”
The 2009 PPRS will become effective on January 1st 2009,36 following re-negotiation,
and will include several options for patient access schemes, whether financially- or
outcome-based, the latter implying flexible pricing based on the clinical evidence produced
and risk sharing between the Department of Health and individual companies.
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6.5.3. Assessment of clinical/therapeutic benefit
Our survey has shown all surveyed countries examine available clinical evidence very
closely (Table 6.2), however, in two countries it appears the strength of the clinical evidence
forms the basis for a classification of drugs as highly innovative, innovative or as me-too.
France applies the principle of therapeutic benefit rendered (Amelioration du Service
Medical Rendu, ASMR), where pharmaceutical pricing and reimbursement is decided by
negotiations between the pharmaceutical industry and a variety of organisations. The
Transparency Committee (CT) initially decides whether or not reimbursement is granted,
the scope of indications for which the drug is to be prescribed, and ultimately determines
rate of reimbursement (ranging from 30% to 65%). However, prices are determined by the
Comité Economique des Produits de Santé (CEPS) based on ‘improvement in medical benefit
rating’ (ASMR) or ‘incremental medical benefit’, as judged by the CT (Table 6.3).
Table 6.3
ASMR categories in France
Amelioration du Service Medical Rendu (ASMR) Group
ASMR 1 significantly innovative and of substantial clinical benefit
ASMR 2
significant improvement in efficacy, and/or amelioration of adverse reactions
ASMR 3 some improvement in efficacy, and/or reduction of adverse reactions,
compared with existing medications
ASMR 4 little improvement of clinical benefit compared with existing products
ASMR 5 no improvement in clinical benefit, as compared with existing products
Source: PPRI, 2007.
37
The ASMR rating is not the sole deciding factor for determining the final price. Although
ASMR 1 to 4 products will be priced higher than their existing alternatives, with ASMR 5
pharmaceuticals not given a price premium compared to existing products, expected sales
levels and external reference pricing are also considered. If the new drug is expected to
increase the overall sales level in that therapeutic group, a lower price than existing drug
may be justified. Overall, CEPS would like to keep prices at or below the EU average.
208
An Italian algorithm was developed to quantify the value of innovation, in the hope of
capturing patients, policy-makers and pharmaceutical companies’ perspectives in the
innovation process.38 The Innovation Assessment Algorithm (IAA) had 3 key aims: first, to
take into account and incorporate different properties of drug innovation; second, to
provide a numeric weight as a measure of the innovative value of a drug; and third, to reassess innovation over time, by incorporating clinical evidence emerging post-marketing
authorization. The final score gives greater weight to earlier ‘efficacy’ branches than
effectiveness branches. While several models have been suggested to explicitly quantify
innovation in such a manner, this model is significant by identifying innovation aspects in
the early-intermediate R&D stage, as well as differentiating between therapeutic
innovation, common innovation and industrial innovation (Table 6.4).
Table 6.4
The IAA algorithm
The IAA algorithm
Stage 1
Stage 2
Stage 3
Subdivided to recognise
indications for which there
was no current satisfactory
Therapeutic Innovation treatment, known molecular
entities but used for novel
indications and unclassified
substances
factors of importance
to the pharmaceutical
industry in the clinical
patient-centred issues,
trial phase, such as
such as compliance,
clinical outcome,
tolerability and the
number of
Classified according to
societal consequences
indications,
patient
whether discovered through
of the new drug
population tested and
an advanced technology (e.g.
Industrial Innovation biotechnology), whether a
type of overall drug
new preparation or
benefit
administrative route, or
whether of limited innovative
value
Common Innovation
Evaluation of Efficacy
Source: Caprino and Russo, 2006.
Evaluation of effectiveness
38
209
Recent evidence suggests analysis of innovation per se is directly influencing policy in
Italy. Indeed, a similar hierarchical scheme devised by the AIFA along similar lines, divides
pharmaceuticals into three broad categories: those for fatal or serious conditions resulting
in permanent disability/hospitalisation, those eliminating or reduce the risk of serious
diseases (e.g. hypertensive treatments), and lastly those for ‘non-serious’ diseases such as
hay fever. Interestingly, a clear distinction is made between pharmacological innovation (i.e.
a new method with necessarily increased efficacy) and technological innovation perhaps not
providing therapeutic innovation (Figure 6.1). Ceteris paribus, the former would be rated
higher than the latter under their new scheme. AIFA have also stressed the importance of
incorporating post-marketing data into their algorithm.
Figure 6.1
Assessing therapeutic innovation in Italy
Source: Atella, 2008, personal communication.
39
Although the IAA algorithm may appear to have high informational requirements, a
similar framework might be useful in structuring the economic information required from
pharmaceutical companies to enable greater transparency of health system priorities. Such
scientific approaches provide a robust and reliable method of quantifying innovation, and
attractive as they simultaneously pacify several stakeholders. The particular model
210
mentioned above also takes into account economic information emerging postauthorisation (ex-post).
6.5.4. Health Technology Assessment in assessing value of innovation
The varying nature and complexity of health technologies, in combination with limited
national budgets, has resulted in tensions between delivering cost-effective health care and
improving or sustaining a country’s manufacturing and research base. As a result, it has
become increasingly important to achieve a balance between affordable health care and the
use of innovative health technologies, including pharmaceuticals. Thus, it is necessary to
both consider the value (in both medical and economic terms) of a product, plus who
benefits from innovation, the optimal usageff, and the appropriate placement in the
spectrum of care. 40
HTA can assist in meeting these challenges by determining which technologies are
ineffective versus effective, and define the most appropriate indications for use of the
technology. 41 Moreover, HTA can serve to validate a new technology and define its role in
health care system. These are important benefits to enable governments to make valuedriven decisions concurrently supports innovation, and garners patients and physicians with
the information needed to make the best treatment choices. 42
However, the effectiveness of HTA in achieving the above benefits, particularly in terms
of encouraging innovation, hinges on properly performed assessments as well as
appropriate implementation and use of subsequent recommendations. HTA can encourage
innovation if the assessments are properly done and consider a wide range of costs and
benefits associated with a new technology, rather than focus solely on acquisition costs. In
particular, adoption costs need to be viewed in terms of broader benefits ensued if a
technology were integrated into the health system, as budget-driven constraints on the
ff
Variation in uptake and diffusion can signify the sub-optimal use of technology. Excess use is signified
when the costs outweigh benefits for any additional level of technology diffusion or use. Under-use can occur
when the foregone benefits outweigh the costs of additional diffusion or use. Both scenarios are sub-optimal,
potentially resulting in economic costs and/or reduced health outcomes.
211
general diffusion of technologies do not necessarily result in the selection of the most
effective or cost-effective products. This may require governments to allow additional
funding and flexibility between budgets allowing expenditure levels are driven by value, as
opposed to arbitrary spending caps.40
The utility of HTA in encouraging innovation and value-added health care depends on
the assessment process, including when and how the review was performed, and resultant
decision-making procedures. In particular, the following issues can potentially affect the
effective use of HTA in meeting these objectives:39, 43-45
•
Delays in the HTA process can result in deferred reimbursement decisions, restricting
patient access to needed treatments.
•
Evidence requirements can pose significant hurdles for manufacturers, particularly
small, innovative companies, potentially discouraging sponsors from pursuing
breakthrough technologies.
•
As HTA becomes widespread, assessments occur earlier in the technology diffusion
process which may introduce greater uncertainty in the process and the potential for
innovations to appear more or less beneficial than when assessed at latter stages.
•
Current assessment methodologies may limit the comparability and transferability
across countries and studies.
•
Lack of transparency, accountability, and stakeholder involvement in the HTA
process can decrease the acceptance and implementation of assessment results.
•
Limited skilled HTA personnel and international collaboration between review
agencies can stymie the efficiency and effectiveness of assessments.
•
Separate processes for organizations dedicated to economic assessments,
reimbursement/pricing decisions and practice guideline development may hinder
the effectiveness and efficacy of the overall decision-making process, leading to
unnecessary duplication of efforts and resource use.
In addition, HTAs are more likely to be used by decision makers if policy instruments
(e.g. reports, practice guidelines) are available to act on the assessment, and if prior
commitments to effectively use the assessments are established. Moreover, as technology
cost-effectiveness and patient demand may change with time, periodic review of HTA
recommendations are important. To achieve these objectives, greater participation and
212
collaboration among stakeholders, particularly HTA personnel, government officials,
industry, health providers and patients, is required.
Without adequate input and
understanding of the HTA process, stakeholders may mistrust the evidence and subsequent
recommendations of the assessment.
Overall, in order for HTA to be of optimal benefit, the assessment process needs to be
linked with innovation and other aspects of policy-making. To the latter, it is important that
HTA recognise the complexities of decision-making, whereby subjective and normative
concerns are duly considered. Otherwise, HTA may be limited in its powers to impact upon
the policy process and subsequent access to new and effective products. The role of HTA in
encouraging innovation and value in health care could be improved by better understanding
and addressing the inherent challenges in the HTA process, as outlined below.
The introduction and growth in HTA in Europe parallels an era in health policy that
places greater emphases on measurement, accountability, value for money and evidencebased policies and practices.
Moreover, the advent of randomised control trials and
subsequent availability of data, growth in medical research and information technology and
increased decentralisation of health system decision-making have all contributed to an
increased need for HTA activities. 46
In Europe, the first institutions or organisational bodies dedicated to the evaluation of
health care technologies were established in the 1980s, initially at the regional and local
level in France and Spain and, later, at the regional level in Sweden in 1987.43, 47 During the
following decade, HTA programmes have been established in almost all countries, either
through the provision of new agencies or institutes, or in established academic units or
governmental and non-governmental entities (Table 6.5). Broadly speaking, such bodies fall
into two general strands: 1) independent (“arms-length”) review bodies that produce and
disseminate assessment reports on a breadth of topics, including health technologies and
interventions, and 2) entities under governmental mandate (e.g., from health ministries)
with responsibilities for decision-making and priority-setting, typically pertaining to the
reimbursement and pricing of heath technologies. The latter type of HTA body serves either
an advisory or regulatory function.
In parallel with establishing HTA entities, many EU countries are investing resources in
HTA and associated evaluation activities. For example, Sweden dedicates €5 million per
213
year on the Swedish Council on Technology Assessment in Health Care (SBU) and the Dutch
Fund for Investigative Medicine spends €8.6 million per year on health evaluations.41
Table 6.5
Institutions and advisory bodies responsible for HTA activities in selected EU
countries (2008)
1. Denmark
2. Finland
3. France
4. Germany
5. Italy
6.
Netherlands
Reimbursement Committee/Danish Centre for Evaluation and
Health Technology Assessment/ Center for Evaluering og Medicinsk
Teknologivurdering (DACEHTA/CEMTV)
• Pharmaceuticals Pricing Board –
PPB (Laakkeiden
hintalautakunta
• Finnish Office of Health technology Assessment (FinOHTA)
• Economic Committee for the Health Products (CEPS)
• Transparency Commission (TC)
• Haute Autorité de Santé (HAS)
• Federal Joint Committee
• Institute for Quality and Efficiency in Health Care (IQWiG)
• Deutsche Agentur fuer Health Technology Assessment (DAHTA)
• Committee on Pharmaceuticals (CIP Farmaci)
• Italian Medicines Agency (AIFA)
National Health Insurance Board/Committee for Pharmaceutical
Aid
8. Sweden
•
•
•
•
9. UK 1
•
•
7. Spain1
Note:
1
•
Spanish Agency for Health Technology Assessment
Catalan Agency for Health Technology Assessment (CaHTA)
Dental & Pharmaceutical Benefits Board (TLV)
Swedish Council on Technology Assessment in Health Care
(SBU)
National Institute of Health and Clinical Excellence (NICE)
National Coordinating Centre for Health Technology Assessment
(NCCHTA)
Scottish Medicines Consortium (SMC)
These are not an exhaustive list of the agencies available in the country.
Source: The authors; adapted and enhanced from Zetner et al., 2005.
43
6.5.5. Role of European institutions
Over the past three years, the High Level Pharmaceutical Forum has provided impetus
for debate and potential coordination among national pharma policy makers. Prior to its
conclusion in 2008, the High Level Pharmaceutical Forum Working Group on Pricing recently
submitted a questionnaire to all Member States with the aim of identifying demand-side
214
benefits viewed as important when assessing the value of an innovative medicine. 48 The
benefits
identified
by the
Member
States
fell
into
three
broad
categories:
therapeutic/clinical benefits, quality of life improvements and socio-economic benefits
(Table 6.6).
Despite EU institutions having no competence in health care policy harmonisation, it has
been an important achievement to gather the Member States and other stakeholders
around the table to understand some of the driving developments at Member State level.
More than anything, “the Pricing Working Group of the High Level Pharmaceutical Forum
has worked out a set of guiding principles which demonstrate that dialogue between
Commission, Member States and multiple stakeholders is possible in an attempt to meet
the needs of patients, payers and industry alike”.49
Table 6.6
The benefits of pharmaceutical innovation1
Benefits of innovative drugs
Clinical/Therapeutic benefits Higher probability of recovery
Faster partial/total recovery
Slower disease progression
Increased ability to cope with disease symptoms
Higher probability of preventing re-emergence of a disease
Survival rate, life expectancy
Reduced side effects
Reduced interactions with other medicines
Higher tolerability
Broader/easier dosing/administration - improved compliance
Quality of Life benefits
Socio-economic benefits
Higher physical self-sustainibility/self-management
Higher psychological self-sustainibilty
Higher social self-sustainability
Higher convenience/comfort for the patient
Avoiding Pandemics
Addressing Resistance
Reduced total cost of medication/treatment
Reduced cost of sick-leave
Higher productivity
1
Note: Adapted from EC Progress Report.
215
6.6. Fostering innovation in oncology: A list of priorities
In order to foster innovation in oncology, a list of priorities emerge in a number of areas:
first, the role of science, research and innovation policy; second, the role of pricing and
reimbursement systems in encouraging and rewarding innovation; third, the continuous
evaluation of oncology drugs; fourth, the encouragement of long-term innovation; and,
fifth, the optimization of resource allocation in health care.
6.6.1. The role of national and supra-national science, research and innovation policy
[I] Guiding government policy-making
The analysis and discussion in chapters 3, 4 and 5 suggest that a new challenging role
is emerging for government, which is both complex and sophisticated, requires scarce
resources be more optimally used, and encourages collaboration and shared decision
making with other stakeholders (charitable and private sectors), beyond partisanship. This
holds in (bio-)medical as well as other areas of research. 50
In an era of globalisation, the role of government in incentivising pharmaceutical
R&D in general, and encouraging oncology R&D in particular, is by no means limited, but
rather, multi-dimensional and pro-active. Government should encourage private innovation,
leveraging investment in innovation to spur economic growth; this can be achieved both
directly, through the funding of basic research in key or/and under-researched areas such as
rare cancers, or indirectly through the use of market mechanisms such as tax incentives.
The role of government is also significant in basic technology research, where the
expectations of long-term public benefit exceed the expectations for private returns to
those undertaking the research.51 The use of collaborative consortia with private co-funding
or cost-sharing should not be excluded but altogether encouraged.
More generally, however, a shift in the way that government encourages innovation
in the private sector is needed. Direct funding of R&D is a useful tool and can leverage
additional resources from the private sector. Yet, encouraging the development of new
cancer drugs and the technologies on which they can be delivered probably requires a
216
proactive stance in indirect measures. For instance, prescriptive and coercive regulations
have been found to be cumbersome, expensive and inefficient tools for incentivising private
investment in technology. It could be the case that output- or performance-based
regulations be adopted in this respect.
Tax incentives (e.g. research and development credits) could be further fine-tuned
and targeted so as to serve specific objectives, for instance targeting areas of work such as
rare diseases and rare cancers. In the same spirit, aspects of intellectual property can be
used to encourage innovation, e.g. through enhanced market exclusivity periods.
As creation of knowledge becomes global and their individual funders, whether
public, private or charitable, can only fund or have partial access to (new) knowledge
development, a new model may be needed in the future where funders of innovation in key
areas such as oncology must learn to cooperate as well as compete. Importantly, open
access to innovation and knowledge may be needed with society reflecting on its
implications (e.g. harnessing the potential of some technology platforms faster) as well as
the requirements to achieve it (e.g. re-thinking the global regulatory environment, or
intellectual property).
[II] Lessons learned from recent initiatives are national and supra-national level
In Europe, the EU Slovakian Presidency in 2008 made headlines with selecting cancer as
its main health priority. As a result, a European Partnership for Action Against Cancer was
formed (2009-2013) which aims to support Member States and stakeholders (academic,
institutions, industry) by creating a framework for identifying and sharing cancer prevention
and treatment information, capacity and expertise.
52
This action will be launched end
September 2009, and funded until 2013 by the EC in addition to the Research and
Development Framework Programme. This action is supported by two other EU level
initiatives: the Innovative Medicines Initiative (IMI) and the European Roadmap (ESFRI). The
IMI is a public-private partnership for medicines development53-55 with an additional focus
on cancer research, while the ESFRI supports clinical trial and bio-banking initiatives.
One of their main goals is cancer research, focusing on translational, transnational and
partnered collaborations. Specifically, their aim is to achieve coordination of one third of
cancer research from all funding sources by 2013. These goals will be driven by multi217
stakeholder working groups undertaking the work directly or, most likely in the case of
cancer research, will monitor work done by outside organisations.
The outlined European programmes have undertaken to combat the fragmented state
of Europe’s cancer research programmes and convert this variability into a cooperative
strength. Although many of these programmes are relatively recent in the history of cancer
drug development (European Partnership Action Against Cancer 2009; FP6, 2002; FP7 2007;
IMI 2007), they are a step towards cohesive cancer research and outcomes. The addition of
public-private partnership is encouraging, and will hopefully make Europe more competitive
globally.
Furthermore, although EC level cancer research governance and funding appears to be
more cohesive than previously, cancer research funding on a charitable level does not. At
country level, there is at least one cancer charity per country, many with overall umbrella
cancer charities supplemented further by specific cancer charities. Although cohesive data
is difficult to come by, significant sums are invested by these organisations in cancer
researchgg. As administrative costs are obviously duplicated by these organisations, this is a
further area for investigation to increase cooperation.
Nationally, many countries explicitly support cancer research – the newer members to
the EU still are exploring, developing or implementing their cancer plans. To date, all cancer
plans support cancer research in Europe, either through their umbrella medical research
organisations (ie UK Medical Research Council) or via specific cancer organisations (ie
German Cancer Research Center). Some countries may have more than one organisation
supporting cancer research, such as via a medical research programme plus a national
cancer programme (ie UK, NL), or may have more than one cancer organisation (ie France).
Thus, it appears, that not only may Europe itself be fragmented, albeit less than before,
there may be national fragmentation as well.
On the other hand, some research institutions could be financially neglected if the work
they perform is not transnational – very likely in the case of very new, very specialised
technology only found in a few locations. The EC initiatives must take care not to neglect
gg
Estimates of minimum €500 million annually (2008).
218
these special cases, as they could be sources of breakthrough technology platforms and/or
treatments. National and charitable funding may be the only source for these special
interest groups; supplementation by public-private partnerships may be an interesting
addition with some protectionist provisions for the public institutions involved.
Meanwhile, American cancer research is less fragmented, solely due to its central
organisation under the National Cancer Institute (NCI) and its funding is directly approved
by the US Congress. Not only does the NCI support molecular research, it also supports
translational research. There is a specific Drug Development Platform whose purpose
somewhat mirrors the European IMI goal of speedier cancer drug entry into the market.
Furthermore, the NCI has an additional purpose of supporting cancer research occurring
in other countries via its International Portfolio. Clinical trials are a large portion of this, but
also collection of international experimental medicines protocols and trials, provision of
education and expertise, and participation at board level on other cancer research
organisations.
The NCI is currently examining its public-private partnership directive, with a proposal
that the NCI would be a ‘safe haven’ for encouraging public-private partnerships, outlining
issues of intellectual property and any other barriers.
Nationally, there is room for
expansion in public-private partnership which the NCI is currently aware of.56 At the FDA
level, there are some projects occurring nationally, only one of which is supporting cancer
research.57 At the state level, there are some public-private partnerships with industry and
academia, usually with private hospitals.
Globally, it appears that cancer research with focus on medicines is still relatively in its
infancy, with only recently organisations and programmes given focus and direction. Publicprivate partnerships appear still in their infancy, both in Europe and the US and could
perhaps benefit from examining other areas with expertise, such as information technology,
which has resulted in major progress.
Fragmentation still occurs, particularly on the
charitable level, and although this may have negative consequences in terms of
administration costs and research duplication by other countries, there may be benefits to
highly specialised research areas still at experimental stage.
[III] Focus on rare cancers and re-thinking regulation
219
Rare cancers belong to the group of rare diseases that are normally defined as diseases
with a prevalence of less than 50 in 100,000. Even when defined more conservatively by
taking into account some peculiarities of natural history and prognosis, rare cancers
represent about 20% of all cases of malignant neoplasms, including all cancers affecting
children and teenagers and many affecting young adults.59 There are significant variations in
incidence and mortality rates for different types of rare cancers. There are also significant
survival differences for the same type of rare cancers between EU member states.60 In
addition to these, there are several problems related to the treatment of rare cancers in
Europe, including variability in access to treatment, variability in the availability of
information about treatment, lack of medical expertise in the management of rare cancers
leading to less than optimal treatment outcomes, potentially higher costs for patients with
rare cancers and their families, lack of registries and tissue banks for rare cancers, and
difficulty in conducting clinical trials.
The recognition of rare cancers as a special case (which, nevertheless, affects a
significant proportion of the cancer patient population) and requires multi-dimensional
action. In this respect, the ESMO recommendations on stakeholder actions and public
policies in rare cancers60 highlight the multiplicity of actions needed to encourage research
and development, access and uptake of new treatments. Such actions relate to reorganising regulation, encouraging research and clinical trials through collaborative actions
and networks, calling for consensus guidelines on multi-disciplinary treatment, addressing
patient access to care, as well as improving access to information on rare cancers and
education of health care professionals.
6.6.2. Need for pricing and reimbursement systems to reward and encourage innovation
Health systems worldwide are struggling with containing costs while improving patient
access and health outcomes. Drug spending has come under particular pressure and
scrutiny, despite accounting for only 10-20% of total system cost and generating significant
value. Managing drug spending should be a priority, however, current approaches to
containment may have a detrimental impact on patient access and health outcomes: top
down price cuts in countries (e.g., Italy) and ‘jumbo grouping’ (e.g., Germany), significant
220
discrepancies in access (e.g., ‘post code prescribing’ in the UK) and, potentially, outcomes
(e.g., Cancer survival rates in the UK vs. France), and delays in getting innovative drugs to
patients as they go through time-consuming HTAs.
A key aspect is timely patient access to innovative, life-saving therapies. Upfront access
restrictions stand in the way of this. A more progressive debate could facilitate the global
goals of improving patient access and health outcomes while managing costs and
appropriately rewarding innovation. Pricing and reimbursement systems can fulfill the goal
of encouraging innovation, provided they take into account a number of criteria.
The first is timely access, ensuring that patients get timely access to innovative
therapies, unfettered by overly restrictive reimbursement, coverage and/or pricing
considerations. The second criterion is value-based reimbursement and could be linked to
an explicit and objective assessment of incremental value relative to existing standards of
care. The third criterion is comprehensive pricing and reimbursement in the sense that the
metrics considered when assessing the value of new treatments and setting reimbursement
levels should include all elements of value. The fourth criterion relates to flexibility. The
total drug benefits and costs to the health system must be assessed over time, by
population segment and in a real-life context - with prices/reimbursement levels adjusted as
new data on relative value becomes available. Finally, a fifth criterion is collaboration.
Payers, providers and manufacturers need to work together, rather than antagonistically, to
explore new pragmatic ways of delivering value to the patient constituency. Each of the
above criteria are discussed in turn.
[I] Timeliness in accessing new and effective treatments
It must be ensured that patients get timely access to innovative new drugs, unfettered
by overly restrictive reimbursement/coverage and/or pricing considerations. This is not an
easy task, partly because payers’ use of restrictive coverage/reimbursement or pricing
policies often interfere with physicians’ ability to make important decisions about individual
patient care. Timely access to care can suffer further as many countries have long
registration, approval and reimbursement times, serving as a blunt instrument to deny
treatment to requiring patients. Finally, the absence of data early on in a new technology’s
221
assessment process is currently taken as evidence of equivalency, heavily weighing
assessments against rewarding pharmaceutical innovation.
What policy makers must focus on is enabling ‘fast track’ approval and reimbursement
procedures to ensure timely access to innovative drugs (e.g., FDA fast-track process for
priority drugs).61 Also, establishing processes for conditional reimbursement / pricing
decisions, enabling prompt access for drugs while real world market data is collected and
analyzed is of great importance. In certain cases, launch prices can be negotiated using data
from Phase III trials, with agreement to reassess pricing decisions 1 year later when Phase IV
trial results become available. Finally, it must be ensured that guidelines and
recommendations provide sufficient flexibility for physician discretion in individual cases
(e.g., reimbursement with prior authorization for drugs that might be recommended for a
small share of the patient population) to meet potentially atypical patient preferences or
clinical circumstances.
[II] The role value-based pricing in improving rationality in decision-making
When payers use coverage, reimbursement and/or pricing mechanisms to manage drug
spending, they should do so in a value-based way- linked to an explicit and objective
assessment of its incremental value relative to existing standards of care.
Current challenges include the following two aspects: First, drug pricing/reimbursement
systems do not always base their decisions on an explicit assessment of a drug’s value, often
relying heavily on cross-country price comparisons and/or intra-country reference price
groups to set prices. Second, pricing/reimbursement systems often struggle with how to
measure and explicitly reward drug innovation, with significant variations in the approaches
used.
There can be positive responses to these challenges. Where controls are exerted over
drug pricing / reimbursement, policy makers could ensure that these are based on
mechanisms that explicitly link pricing/reimbursement decisions to an assessment of a
drug’s value. Finally, developing explicit mechanisms to appropriately reward valuable
innovation via drug pricing/reimbursement (when the drug offers an incremental benefit
over the existing standard of care as measured in a comprehensive way) would be an
important step.
222
[III] Societal approach and other metrics
When assessing drug value and setting pricing/reimbursement levels, all elements of
value, including societal, should be included. However, when value is assessed,
pricing/reimbursement systems frequently choose to focus on value exclusively from the
healthcare system (payer) point of view rather than the broader societal or
patient/physician (e.g., consider cost offsets to the healthcare system such as hospital stays
and/or other drug costs avoided, but not from increased worker productivity or provider
efficiency). Another problem is that most evaluations of drug costs are based on list prices,
rather than actual observed net costs in a treatment setting.
It is imperative that standard guidelines for assessing benefits of drugs based on a
broader range of applicable metrics are established. These should include humanistic,
patient-focused benefits such as quality of life, (QoL) longer-term direct cost offsets, indirect
system costs that might or might not be covered by payers such as worker productivity, and
benefits to caregivers as well as patients (e.g., enhanced patient and physician convenience
that translates into improved compliance and better outcomes). Further, new standards and
tools to more accurately and consistently assess the more challenging metrics may need to
be developed (e.g., patient reported outcomes such as QoL).
[IV] Risk-sharing
Risk sharing refers to a contractual arrangement between a healthcare payer/provider
and a supplier. Traditionally, payers absorb all risks associated with purchasing new medical
technologies. In this regard, payers make a decision on whether the technology offers an
effective use of their funds, based on the information available at the time of launch. Risk
sharing is an attempt to redistribute the balance of risk between the payer and the supplier
of the medical technology, and typically involves the supplier of the medical technology
providing a ‘guarantee’ relating to the performance of the technology. The guarantee may
relate to one or more outcomes of treatment.62 These could include for instance (a) clinical
outcomes, (b) humanistic or quality of life outcomes, (c) resource use (for example, a
reduction in hospitalisations), (d) financial outcomes (for example, a reduction in the
amount spent treating a condition), and (e) economic outcomes (for example, the
achievement of a particular cost effectiveness threshold).
223
As the pressure on health care budgets intensifies and the cost of some of the more
novel treatment remains high, it is likely that the use of risk sharing agreements will
intensify in the future. This may be on two fronts: first, in terms of admitting new
treatments onto national formularies, and second, in terms of enabling faster uptake.
Enabling innovative pricing solutions, e.g. through pilot schemes making selected innovative
medicines available for time-limited periods,63 or through patient-specific franchise
schemes, could contribute to faster access and uptake of new therapies. This would have
particular application in the case of oncology due to the limited number of patients.
[V] Flexible decisions
Total drug benefits and costs to health systems need to be assessed over time and in a
real-life context, with prices/reimbursement levels adjusted as new data on relative value
becomes available.
In many countries though, value assessments are conducted at drug launch, using only
data collected during the treatments’ clinical development process; as new data becomes
available, prices need to be allowed to be in line with demonstrated value. Further, the
value of a drug and its price is typically set based on the initial indication, with little or no
flexibility to evolve it or change it for different indications in which the dosing and/or value
over existing therapies could be significantly different. Optimal mechanisms must be
determined, in order to allow for drug price/reimbursement variations across different
indications/sub-populations based on value propositions.
Pragmatic and viable processes must be created, so that pricing/reimbursement levels
are allowed to fluctuate both up and down over time as meaningful new data becomes
available, including potential for ‘temporary’ pricing/reimbursement for novel drugs with
limited evidence at launch. Finally, it is important to establish appropriate requirements for
ongoing data collection on the part of drug manufacturers to provide support for ongoing
price/reimbursement adjustments.
224
[VI] Collaboration between stakeholders
Payers, providers and manufacturers must work together, not antagonistically, to
establish pilots to investigate new pragmatic ways of managing drug spend, avoiding
wholesale ‘top down’ change.
Unfortunately, most pricing/reimbursement systems are not collaborative in their design
and operation, with payers often issuing top down directives, little sharing of data, and
assessments made by relatively closed, non-transparent and often political HTA bodies. In
addition, drug regulators give little or inconsistent guidance on trial design. Finally, reform
often include multiple changes to the current system wholesale, without a clear and open
debate of the alternatives and/or productive piloting before roll-out.
In order to face these challenges, an inclusive process for defining pragmatic, effective
changes to drug approval and pricing/reimbursement approaches must be developed,
ensuring these are transparent to all (e.g., manufacturers understand what trials /data will
be required for drug approval, reimbursement and pricing decisions well in advance). Pilots
to test new approaches to drug pricing/reimbursement must also be established (i.e., in the
areas outlined in above points I through IV) before large-scale implementation. Finally,
effectively sequencing and staging the roll-out of any changes (e.g., begin with a few newly
launched drugs and expand as required) rather than attempting to enact wholesale change
is an important part of the process.
[VII] Minimising externalities
The above will be able to deliver significant benefits if the key negative externalities
often associated with the process of enabling access are minimised or altogether
eliminated. Such negative externalities often emerge from international price referencing
and comparisons, as well as exchange rate differentials and depreciations/appreciations.
6.6.3. Continuous evaluation of oncology drugs
Although ex-ante evaluation provides manufacturers with the incentive to invest in
gathering the evidence that the health service requires to make approvals and also
encourage innovation in areas/therapies where a substantial clinical benefit can be
225
demonstrated, one drawback of the use of ex-ante as opposed to ex-post evidence is that
there will be uncertainty surrounding the cost-effectiveness of the treatment outside the
RCT setting at the time of launch. Although further ex-post reviews can also be suggested,
these may be difficult to ensure as once a pharmaceutical product is approved, the incentive
to carry out further trials is diminished and may even be deemed unethical. There is also
concern that if ex-post evaluation slips, the evidence-based approach to health systems
could be compromised.64 Nonetheless, a balance between the value of the economic
information surrounding the drug and the value of availability of the drug to patients needs
to be achieved (as is often emphasised in HTA).
On the other hand, it should be made clear to pharmaceuticals that ex-post evidence is
as crucial as ex-ante evidence in proving the value of a new treatment. In order to do this,
there needs to be acceptance of data obtained in naturalistic settings, and methodologies
on how best to extract value from such data need to be strengthened. Ownership of such
data is also important, as the cost associated with gathering evidence is substantial creating this evidence should provide the scope for collaboration between the payer
community and manufacturers.
6.6.4. Encouraging long-term innovation
Innovation - whether breakthrough or incremental - can lead to greater subsequent
understanding of the aetiology of a disease (i.e. there could be said to be a positive
externality from discovery and use of a new drug). The underlying premise in this regard is
that knowledge and innovation have a cumulative impact on the understanding of a disease
and that impact is often not quantifiable. This may have important dynamic implications for
future R&D.
A meaningful pricing system able to deal with both the short- and the long-term
implications of and benefits from innovation would probably be complicated to create.
Whilst it is often very difficult to anticipate the future gains from innovation and directly
incorporate these into a pricing system, governments must encourage such developments
to take place. Stratified pricing arrangements such as these seen in France would send a
clear message to the research-based industry that innovative products have recognisable
226
value within the pricing system, although, clearly, the starting point vis-à-vis which ASMR a
new medicine represents may be different for different stakeholders. Importantly, there
need to be separate (although interconnected) rules targeting value for money and
providing incentives to foster long-term innovation.
6.6.5. Optimizing resource allocation in health care
The way resources are allocated does not necessarily guarantee their optimal use. There
may be cases of resource misallocation, which could potentially lead to waste and might
also affect access to care. Even if we accept that health care resource allocation operates in
silos, evidence shows that even the pharmaceutical budget can be further optimised.
Further focus is needed on the demand-side and the behaviour of clinicians, and very
importantly, on the use of information systems in real time, both by payers as well as
providers. For instance, a recent study found general practitioners performed no better
than chance at ranking drugs in 6 therapeutic groups in order of list price.16
A case where a potentially significant resource re-allocation could take place is the offpatent segment. Despite strong emphasis of European governments in generic medicines
over the past two decades, recent evidence suggests that the savings accruing to health
insurers from the more intensive use of cheaper generics may have not been realised.65
There are three dimensions of savings that contribute to the total savings foregone to
health insurance from greater use of generics. The first and most obvious dimension
reflects the level of generic penetration in a molecule market, post patent expiry. Generic
penetration is a measure of the share of a molecule market that is purchased as generic.
Yet, examining the level of generic penetration in some key market, one realises the
unfulfilled potential in some of them. While the UK and Germany lead with 76% and 66%
generic penetration respectively, generic penetration in Spain is 50% in France 33% and in
Italy 19%. Italy, France and Spain could realize the largest savings by increasing their generic
penetration, although there is significant room for improvement in all study countries for
these molecules.
The second dimension of savings that contributes to total foregone savings is the price
difference between the originator drug and the generic equivalent.
227
The larger the
difference between the two and the smaller the generic penetration, the greater are the
foregone savings to health insurance.
Finally, the third dimension that contributes to total foregone savings is the difference
between the actual purchased generic price and the lowest generic price. This dimension
reflects the degree of efficient purchasing in the generics market itself, independent of
generic penetration and originator brand prices. Often this dimension of savings is the most
neglected by policymakers, despite the fact that in some cases, the generic price spread may
exceed ten to one from highest to lowest. By estimating the effect of additional generic
penetration that could occurhh and assuming that health insurers are in a position to
procure more cost effectively to the lowest available price on the market, the additional
savings to health insurance (or the savings that currently health insurance foregoes) can be
calculated. Table 6.7 shows the total savings forgone for 5 genericised molecules across
seven countries: improved genericization and more efficient purchasing could have saved
health insurers over $3 billion in 2004, amounting to a savings on current sales in the order
of 43.8%.
This has significant implications for health insurance as it overpays for commodity
products that can be acquired more cost effectively, as recent evidence from the
Netherlands suggests. 66, 67 It also has significant implications for the type of medicines that
health insurance is able to finance, given a relatively inelastic budget. Should a resource
reallocation occur from the commodity part of the market to the top end of the market,
patient access to needed modern medications could improve in many instances. At the
other end of the spectrum, evidence also suggests that the uptake of new cancer drugs is
slow and inadequate in many countries and leads to significant inequities in access.68
The important message from this discussion is that the uptake and diffusion of
innovation may require resource reallocation without compromising patient quality of care,
but in itself could have positive implications for access, equity and quality. In pursuing this
re-allocation where possible, health insurers may be providing a signal and an indirect
incentive to innovators to continue their effort.
hh
And which could be equal to the highest rate of generic penetration at the molecule level in a given
country.
228
Table 6.7
Generic policies, savings foregone and impact on stakeholders, 2003-2004, seven
countries1 (based on five off-patent molecules2)
2003
2004
(US$ million)
(US$ million)
Outlays for generic medicines by health insurance
(based on actual generic sales)
6,467.4
6,899.2
Outlays through efficient purchasing and improved
genericisation
4,430.2
3,899.7
Efficiency loss (potential saving) to health insurance
2,218.6
3,024.9
Saving to health insurance as a percent of current
sales
34.3%
43.8%
Impact (current gain) on generic manufacturers
1,258
1,724.2
Impact (current gain) on wholesalers
131.3
179.0
Impact (current gain) on pharmacies
718.8
980.0
Impact (current gain) on VAT or sales tax
110.3
150.4
Notes:
1
UK, Germany, France, Italy, Spain, Canada, USA.
2
Omeprazole, simvastatin, lisinopril, paroxetine and metformin. Simvastatin was under
patent in the USA in 2003 and 2004, therefore no additional savings can be calculated in this
particular case.
Source: Kanavos et al, 2008.
65
229
6.7. Concluding remarks
This chapter has illustrated that innovation in the pharmaceutical sector brings
significant tangible benefits to the patient, the health care payer and the economy in terms
of clinical and economic effects. It concludes that, from a historical perspective, the
socioeconomic and monetary benefits from pharmaceutical innovation are significant as
evidence demonstrates, but that the incentives provided by society to continue the process
of innovation are often blurred by the frequent policy objective to satisfy reimbursement
cost control and inertia. The chapter also concludes that cost effectiveness considerations,
in the context of health technology assessment, are an important factor in determining the
value of new medicines, but may need to be supplemented with a broader incentive
structure that takes into account not only static (single technology, in the short-term), but
also dynamic considerations (innovation as a whole over the longer term). Finally, the
chapter proposes that in valuing pharmaceutical innovation it is important to consider the
context in which such innovation is taking place, together with strategic issues in resource
allocation in the entire pharmaceutical value chain and elsewhere in health care.
230
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7. CONCLUSIONS AND POLICY IMPLICATIONS
7.1. Introduction
Cancer is becoming of increasing importance in society both on an individual and
broader level, with governance playing a growing role. Cancer incidence has been globally
increasing steadily over the past half century due to greater longevity, lifestyle (particularly
smoking) and environmental influences, as well as improved diagnostics. Cancer mortality is
now in most high income countries the first or second cause of overall death, while in
middle and low income countries it is slowly increasing its ranking. Not only is cancer having
an economic impact due to its increasing contribution to health care costs, it also is
associated with high indirect costs due to the loss of ability to work.
Cancer treatments have improved tremendously over the past three decades and as a
result outcomes have improved. The 5-year relative survival rates (1990-94 diagnosis) for
three major cancers average globally for breast cancer 75% (range 40-82%), prostate 63%
(20-89%) and colorectal 52% (22-63%). Treatments consist now of surgery, radiotherapy and
chemotherapy, either independently or more often in combination, in addition to the
newest addition to the arsenal, targeted biological treatments. This latter addition has been
proven to be most successful with late stage cancers which until now have had dismal
outcomes, often with less than 10% 5-year survival rates.
Targeted biological treatments are now the newest direction in cancer research and
development (R&D) with greatest promise for future oncology drugs.
New oncology
discoveries have uncovered genomic complexities, finding each tumour has a unique generic
code. This complexity is compounded by oncology research methodology where ill, in place
of healthy, individuals are test subjects, new molecules are tested in combination with best
practice consisting of other treatments, as well as large numbers of cancer sites each with
its own genetic fingerprint. As a result, oncology pharmacology R&D has the highest failure
rate, particularly during Phase III, and 20% higher costs than other new molecular entities
(NME). Despite this failure rate, this is one of the most active portions of total R&D, with
new compounds in development phase increase twofold from 2005-2009.
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Due to this complex interplay of oncology and pharmacology R&D, this report maps current
oncology funding and management of R&D structures in Europe and the USA, examining
public-private relationships and current oncology R&D strategies, as a result producing
oncology innovation recommendations. Specifically, the objectives of the report are (a) To
map current funding and management of oncology R&D via questionnaire and interviews of
oncology experts; (b) To produce a high-resolution bibliometric analysis of oncology drug
R&D in order to better understand the public-private mix in research activity; (c) to
investigate the cumulative life-time funding of specific oncology drugs; (d) to review current
public policy affecting oncology drug R&D, specifically, public R&D investment policies,
transnational investment policies, regulatory policies, and drug reimbursement policies; and
(e) to propose future oncology policies supporting the R&D process.
7.2. Funding
The report captured both public and private funding of oncology R&D, important in
estimating long-term outlook for cancer outcomes and oncology care.
Generally, there are two types of motivation for publicly funded research: economical
and political / social reasons. The former helps create new knowledge and new products
thus contributing to the wealth of a country, while the latter represent a social driver as
cancer is a significant and public disease. Both are important together to create new
knowledge, new treatments and ultimately improve oncology patient outcomes.
7.2.1 Results of public and private research funding organisations survey
Public oncology R&D funding can be sourced from a variety of sources: national
governments, regional authorities, charities, non-governmental organisations (NGOs) and
supranational organisations. This funding can be directly tagged for oncology research from
these organisations or indirectly flow into oncology research via overall budgets (ie hospital
budgets).
153 public research funding organisations (RFO) in the EU (UK 19, France 12, Belgium 12,
Italy 11) and 21 in the USA were identified satisfying the criterion of greater than €1 million
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annual oncology R&D spending. The EU RFOs spent collectively €2.79 billion while the
American RFOs spent €5.8 billion in 2007. However, the EU figure does not include the
European Commission investment (through programmes such as FP6, FP7, or IMI) and is
likely to be an underestimate. If the estimated annual average spend on cancer research of
is included, the EU figure is closer to €3 billion.
After the USA, the UK was the largest investor in oncology R&D (€1.1 billion) followed by
Germany (€426 million), France (€389 million) and Italy (€233 million). Accounting for
population differences still found the USA and UK at the top (€19, €18 per capita
respectively) followed by Sweden (€12.1), the Netherlands (€8.8) and Norway (€7.2).
Specific oncology drug development had similar absolute leaders (USA €1.67 billion, UK
€305 million, France €67 million) and per capita leaders (USA €5.60, UK €5.1, Sweden
€2.22).
Although comparing the US and the UK appear to have large funding differences, these
are reduced when only the EU 15 are compared, and further still when examining trends, as
the EU has increased funding 34.7% from 2004 to 2007 while the USA only increased 9.7%.
This trend furthers When direct and indirect funding are added together, finding the EU
investing 0.011% of GDP, or €3.64 per capita, and the USA 0.018% GDP, or €5.74 per capita.
With the exception of the US and the UK who have strong national cancer strategies and
national funding, the remaining countries do not appear to have coherent national
strategies, rather favouring an ad hoc approach to oncology R&D funding. Examination of
the direction of RFOs spending found treatment, including oncology drug development,
predominant, ranging from under 10% to over 70% of the RFOs investments.
Although government funding remains the major source of public funding, charitable
investment in oncology R&D cannot be ignored. In Europe, this amounted to over €300
million in 2007, and in the USA over €230 million.
Examination of private spending found the 17 top pharmaceutical companies globally
spending collectively €3.1 billion in 2004, with 59% sourced from European companies.
With regards to public-private enterprises, these are becoming of increasing importance,
particularly in Europe. Currently, 68% of oncology drug R&D projects in the USA have joint
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funding, compared to 57% in the EU and 31% in the rest of the world. This is rapidly
changing with redirection of focus.
The European Commission (EC) has since the millennium redirected its focus on
oncology R&D, specifically for translational and transnational projects.
Its previous
Framework Programme (FP) 6 (2002-2006) invested €480 on 108 projects and the current
FP7 (2007-2013) has so far invested €265 on 65 projects with more to date. Wider
European cooperation, long-term impact and translational research are key to successful
funding. The Innovative Medicines Initiative (IMI) is a public-private partnership focusing on
speeding up the process of drug discovery to treatment.
The USA’s National Cancer Institute (NCI) has a similar programme, the Drug
Development Platform, to speed up drug discovery to marketplace. Overall the NCI’s
oncology investment was $4.83 billion, providing funding to public, private and academic
research activities both nationally and internationally.
Other countries also invest in
oncology R&D, some as molecular and some as translational.
7.2.2 Policy implications
Six issues came to light with our oncology public funding survey.
First, there are funding gaps between the USA and Europe and within Europe between
countries.
European dominating countries are France, Germany, Italy and the UK in
absolute terms, while in per capita terms the Netherlands and Sweden are the strongest
funders, and the newest European Member states are the weakest.
Europe has
considerably increased its funding since 2004, reflecting increased political interest, both
economically and socially, in oncology research outcomes.
Second, it appears publicly funded research is more likely to support basic rather than
applied research, industry supporting the latter.
Third, research funding appears fragmented in Europe, with duplication in some areas
and insufficiencies in others. The EC creation of the Framework Programme, with focus on
transnational and translational research hopes to rectify this rather than create another
layer of bureaucracy.
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Fourth, indirect funding and charitable funding are two additional areas of oncology
R&D investment. In Europe in particular, these sources can be considerable. Annually in
Europe, the main oncology charities invest over €500 million in cancer research, while
almost half of annual oncology R&D comes from indirect sources such as academia and
healthcare systems. This is significantly greater than invested in the USA, and an often
overlooked area of oncology R&D funding.
Fifth, the main investors in private oncology R&D are pharmaceutical companies, whose
investment into research has increased steadily over the years with significant portions (712%) earmarked for oncology. Despite this investment, the New Drug Applications have
remained flat and less New Chemical Entities have been approved in recent years. This has
driven large pharma companies to invest more in in-license start-up biotech companies, as
well as pursue defined public-private partnerships (PPP).
Sixth, in oncology in particular, PPP have become more interesting due to the
uniqueness of oncology research itself in addition to its complexity. Collaboration of
industry with academia can reduce economic risk and smooth the operational process.
Many pharma companies have now placed their research centres close to relevant major
academic areas. More than half of all oncology research in Europe and the USA is now
through PPP, and likely to increase in the future.
7.3 Capturing investment in oncology through research outputs
The bibliometric analysis was a useful addition to our report, giving us information on
research outputs with regards to total output, per country, per cancer site, partnerships and
industry investment. This information is useful to pinpoint leaders and opportunities for
oncology investment and shows where future breakthroughs may come from in what
discipline.
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7.3.1. Results of the bibliometric survey on oncology research output
Bibliometric analysis of 19 cancer drugs, selected for their treatment success, published
in the Web of Science between 1963 to mid-2009 produced 28,752 papers for analysis.
Paper outputs rose from 200 annually in 1980 to 2000 annually by 2007-08. Examination of
15 main oncology research countries found the USA the leader (33%) followed by Japan
(10.6%), Italy (7.5%) and the UK (7.1%).
Although international collaboration is increasing, neighbouring countries still favour
each other (USA:Canada, UK:NL). An examination of the 15 countries versus the 19 selected
oncology drugs found that countries appear to concentrate on certain drugs and produce
less research on others. Furthermore, the oncology research portfolio per country had poor
correlation to its internal oncology burden, with the exception of melanoma in Australia.
Initially, the USA and Europe dominated oncology research outputs, however, this is
changing dramatically with the Rest of World (RoW) beginning to dominate.
The type of oncology research performed changed with time from basic to clinical,
although per drug this was not necessarily the case. Different countries produced different
types of research (ie basic: India, China; clinical: Spain, Greece), with 15% of papers
describing phased clinical trials, primarily Phase II.
The presence of 26 leading pharma companies, including the 12 associated with
development of the 19 selected drugs, among the addresses of the papers occurred on 1589
papers, or 5.5% of the total. Dominating companies responsible for oncology paper outputs
were Aventis (274 papers), AstraZeneca (173) and BristolMyerSquibb (155).
7.3.2. Policy implications
The results show that oncology research has increased dramatically over the years, and
continues to grow even for older compounds. Main oncology R&D countries are the US,
Japan and Europe, although China recently has significantly increased its output, while
collaborations between countries have remained stable since the 1990s. This latter finding
is surprising, as proximity still appears to play a major role in international collaborations,
despite the advances in global markets and communication.
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Further, it appears the burden of a specific disease is not reflected in its oncology R&D
output, either nationally or internationally. In addition, there appears to be a gradual
mixing of basic to applied research, which means that policy approaches for translational
research must understand and support this. It appears also, that this research has a variety
of funding mechanisms supporting it, from industry, government and philanthropic sources.
Without the basic underlying research, translational research cannot be completed, thus
completely ignoring basic research through funding and policy will have long-term negative
impacts.
7.4 Public Policy in Oncology Development
A unique aspect to this report is a comprehensive survey of oncology clinicians with
regards to their opinions on public policy issues affecting cancer, never before completed.
This survey was unique in its elicitation of oncology issues influenced by public policy, with
both quantitatively and qualitatively responses, in addition to its international responders.
7.4.1. Results of our public policy survey of oncology clinicians
Our survey of leading oncology clinicians globally on public policy issues surrounding
oncology R&D yielded a number of interesting results. Respondents felt strongly that
public-private partnerships (PPP) were the way of the future, however, how this partnership
should best be defined was not clearly resolved. Some felt financial incentives were
important while others did not and the length of private support was disputed (from neutral
to agree).
Differences in country of origin occurred, with Europeans less agreeable to
nationalisation of drug development than Americans and Canadians.
Americans felt
reimbursement policies were less important to success than the RoW, while all agreed that
the degree of national public sector investment was inadequate to meet future oncology
demands.
Further, it was agreed that the current R&D models were unsufficient for specific
oncology needs with re-examination in order. Potential new policies should include greater
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transnational cooperation, support of translational research and a degree of institutional
involvement. Regulatory bottlenecks must be closely examined and quickly resolved to
meet future oncology needs. Unresolved was ideal degree of funding by public versus
private, in particular to meet long versus short-term goals. Overall it was clear that
continued investment in intellectual public research remains important to meet best cancer
outcomes.
7.4.2. Policy implications
Despite the globalisation of the cancer burden, surprisingly little thought has been given
to the nature of international PPP in any domain of cancer research with most of the focus
being placed upon carcinogen control and national cancer control programmes.
In the domain of cancer drug development our data from key opinion leaders clearly
shows that both public and private sectors are needed. While there might be disagreement
over whether the current balance of public and private sector is correct, what is absolutely
clear is that new models for this relationship are urgently needed. An integral part of this
finding was that the key opinion leaders were clear that the overall model of R&D in cancer
drug development needs to be changed to reduce attrition rates, increase the rate and
sophistication of parallel biomarker development, and work on the vast number of
combination regimens and indications necessary for the next generation of cancer drugs.
In particular, the key areas for policy development to arise for PPP were:
•
Strong institutional support and dedicated streams of funding from public research
funding organisations.
•
New models that increased the freedom-to-operate in terms of following important
translational leads within the context of specific projects. This would be achieved by
improved support, light touch governance and a substantial decrease in
administrative bureaucracy at every level (national legislative, private-contractual,
public-contractual).
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•
Partnerships that supported trans-national co-operation and collaboration focused
on key cancers, including those traditionally viewed as ‘orphan’ and thus not
particularly commercially attractive.
The need for these new policy approaches was, however, tempered by a view that these
partnerships should be in the ‘public good’, subject to high quality peer review and upon
completion fully and publicly disclosable.
The findings also indicate that the intellectual environment (“trained drug development
faculty embedded in centres with sufficient critical mass”) and infrastructure provision were
considered the most important areas for institutional and national policies. Many of the
faculty commented that the time had come to be more rational about which major
technologies a centre needed to build in and which they should ‘have’ by dint of strategic
alliances with other groups.
While public funding has been recognised as essential for proof-of-concept work feeding
into downstream product development, there is a clear view that national RFO’s and
institutions have a broader role in providing dedicated clinical facilities, as well as specific
facilities to support development work in such areas as novel biologicals.
Finally, a number of countries clearly identified over-regulation and reimbursement of
new cancer drugs as critical policy issues. The issue of over-regulation continues to
overshadow all aspects of public sector clinical cancer research and this remains one of the
greatest threats to the future for both public and private sectors.
7.5. Fostering innovation in oncology: A list of priorities
In order to foster innovation in oncology, a list of priorities emerge in a number of areas:
first, the role of science, research and innovation policy; second, the role of pricing and
reimbursement systems in encouraging and rewarding innovation; third, the continuous
evaluation of oncology drugs; fourth, the encouragement of long-term innovation; and,
fifth, the optimization of resource allocation in health care.
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7.5.1. The role of national and supra-national science, research and innovation policy
(I) Guiding government policy-making
In an era of globalisation, the role of government in incentivising pharmaceutical
R&D in general and encouraging oncology R&D, in particular, is by no means limited, but,
rather, multi-dimensional and pro-active. The active involvement of government can be
achieved both directly, through the funding of basic research in key or/and underresearched areas such as rare cancers, or indirectly, through the use of market mechanisms
such as tax incentives.
The role of government is also significant in basic technology research, where the
expectations of long-term public benefit exceed the expectations for private returns to
those undertaking the research. The use of collaborative consortia with private co-funding
or cost-sharing should not be excluded but altogether encouraged.
A shift in the way that government encourages innovation in the private sector is
needed. Direct funding of R&D is a useful tool and can leverage additional resources from
the private sector. Yet, encouraging the development of new cancer drugs and the
technologies on which they can be delivered probably requires a proactive stance in indirect
measures. For instance, prescriptive and coercive regulations have been found to be
cumbersome, expensive and inefficient tools for incentivising private investment in
technology. Rather, output- or performance-based regulations could be adopted in this
respect.
Tax incentives (e.g. research and development credits) could be further fine-tuned
and targeted so as to serve specific objectives, for instance, targeting areas of work such as
rare cancers. In the same spirit, aspects of intellectual property can be used to encourage
innovation, e.g. through enhanced market exclusivity periods.
As the creation of knowledge becomes global and individual funders of new
knowledge creation, whether public, private or charitable, can only but fund or have access
to a finite fraction of (new) knowledge development, a new model may be needed in the
future, where funders of innovation in key areas such as oncology must learn to cooperate
as well as compete. Importantly, open access to innovation and knowledge may be needed
and society needs to reflect on the implications of this (e.g. harnessing the potential of
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some technology platforms faster) as well as the requirements to achieve it (e.g. re-thinking
the global regulatory environment, or intellectual property).
(II) Lessons learned from recent initiatives at national and supra-national level
Research funding programmes operating at European level have undertaken to combat
the fragmented state of Europe’s cancer research programmes, convert this variability into a
cooperative strength as well as pay particular attention to translational research. Although
many of these programmes are relatively recent in the history of cancer drug development,
they are a step towards cohesive cancer research and outcomes. The addition of publicprivate partnership is encouraging, and will hopefully make Europe more competitive
globally.
Although EC level cancer research governance and funding appear to be more cohesive
than previously, cancer research funding on a charitable level does not. There is at least one
major cancer charity per country, many with overall umbrella cancer charities
supplemented further by specific cancer charities. Although cohesive data is difficult to
come by, significant sums are invested by these organisations in cancer research. As
administrative costs are obviously duplicated by these organisations, this is a further area
for potential increase in cooperation.
Nationally, many countries explicitly support cancer research – the newer members to
the EU still are exploring, developing or implementing their cancer plans. To date, all cancer
plans support cancer research in Europe, either through their umbrella medical research
organisations (ie UK Medical Research Council) or via specific cancer organisations (ie
German Cancer Research Center). Some countries may have more than one organisation
supporting cancer research, such as via a medical research programme plus a national
cancer programme (ie UK, NL), or may have more than one cancer organisation (ie France).
Thus, it appears, that not only may Europe itself be fragmented, albeit less than before,
there may be national fragmentation as well.
On the other hand, some research institutions could be financially neglected if the work
they perform is not transnational – very likely in the case of very new, very specialised
technology only found in a few locations. EU-wide initiatives must take care not to neglect
these special cases, as they could be sources of breakthrough technology platforms and/or
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treatments. National and charitable funding may be the only source for these special
interest groups; supplementation by public-private partnerships may be an interesting
addition with some protectionist provisions for the public institutions involved.
Meanwhile, American cancer research is less fragmented, solely due to its central
organisation under the National Cancer Institute (NCI) and its funding is directly approved
by the US Congress, supporting both molecular research and translational research. There is
a specific Drug Development Platform whose purpose somewhat mirrors the European IMI
goal of speedier cancer drug entry into the market.
Furthermore, the NCI has an additional purpose of supporting cancer research occurring
in other countries via its International Portfolio. Clinical trials are a large portion of this, but
also collection of international experimental medicines protocols and trials, provision of
education and expertise, and participation at board level on other cancer research
organisations.
The NCI is currently examining its public-private partnership directive, with a proposal
that the NCI would be a ‘safe haven’ for encouraging public-private partnerships, outlining
issues of intellectual property and any other barriers.
Globally, it appears that cancer research with focus on medicines is still relatively in its
infancy, with only recently organisations and programmes given focus and direction. Publicprivate partnerships appear still in their infancy, both in Europe and the US and could
perhaps benefit from examining other areas with expertise, such as information technology,
which has resulted in major progress. Fragmentation still occurs, particularly at charitable
level, and although this may have negative consequences in terms of administration costs
and research duplication by other countries, there may be benefits to highly specialised
research areas still at experimental stage.
(III) Rare cancers, regulation and incentives
Rare cancers, even when defined more conservatively by taking into account some
peculiarities of natural history and prognosis, they represent about 20% of all cases of
malignant neoplasms, including all cancers affecting children and teenagers and many
affecting young adults. There are significant variations in incidence and mortality rates for
different types of rare cancers. There are also significant survival differences for the same
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type of rare cancers between EU member states, as there is variability in access to
treatment, the availability of information about treatment, and a lack of medical expertise
in the management of rare cancers.
The recognition of rare cancers as a special case, requires multi-dimensional action to
encourage research and development, access and uptake of new treatments. Such actions
relate to re-organising regulation, encouraging research and clinical trials through
collaborative actions and networks, calling for consensus guidelines on multi-disciplinary
treatment, addressing patient access to care, as well as improving access to information on
rare cancers and education of health care professionals.
7.5.2. Encouraging and rewarding innovation through the reimbursement system
Health systems worldwide are struggling with containing costs while improving patient
access and health outcomes. Drug spend has come under particular pressure and scrutiny,
despite accounting for only 10-20% of total system costs. Managing drug spending should
be a priority; however, current approaches to containment can be blunt and regressive, with
detrimental impact on patient access and, potentially, health outcomes. Pricing and
reimbursement systems can fulfil the goal of encouraging innovation, provided they take
into account a number of criteria.
The first among them is timely access, ensuring that patients get timely access to
innovative therapies, unfettered by overly restrictive reimbursement, coverage and/or
pricing considerations. In order to do that, a number of actions can be operationalised:
there can be ‘fast track’ approval and reimbursement procedures to ensure timely access to
innovative drugs (e.g., FDA fast-track process for priority drugs). In addition, establishing
processes for conditional reimbursement / pricing decisions, enabling prompt access for
drugs while real world market data is collected and analyzed is of great importance. In
certain cases, launch prices can be negotiated using data from Phase III trials, with
agreement to reassess pricing decisions 1 year later when Phase IV trial results become
available. Finally, it must be ensured that guidelines and recommendations provide
sufficient flexibility for physician discretion in individual cases (e.g., reimbursement with
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prior authorization for drugs that might be recommended for a small share of the patient
population) to meet potentially atypical patient preferences or clinical circumstances.
The second criterion is value-based reimbursement. This could be linked to an explicit
and objective assessment of incremental value relative to existing standards of care.
The third criterion is comprehensive pricing and reimbursement in the sense that the
metrics considered when assessing the value of new treatments and setting reimbursement
levels should include all elements of value, including societal aspects.
The fourth criterion relates to flexibility. The total drug benefits and costs to the health
system must be assessed over time, by population segment and in a real-life context - with
prices/reimbursement levels adjusted as new data on relative value becomes available. A
fifth criterion is collaboration. Payers, providers and manufacturers need to work closer
together, to explore new pragmatic ways of delivering value to the patient constituency.
Finally, it is important that standard guidelines for assessing benefits of drugs based on a
broader range of applicable metrics are established. These should include humanistic,
patient-focused benefits such as QoL; longer-term direct cost offsets; indirect system costs
that might or might not be covered by payers such as worker productivity; benefits to
caregivers as well as patients (e.g., enhanced patient and physician convenience that
translates into improved compliance and better outcomes). New standards and tools for
more accurately and consistently assessing the more challenging metrics may need to be
developed (e.g., patient reported outcomes such as Quality of Life (QoL)).
7.5.3. Risk sharing
Traditionally, payers absorb all risks associated with purchasing new medical
technologies. Risk sharing is an attempt to redistribute the balance of risk between the
payer and the supplier of the medical technology and typically involves the supplier of the
medical technology providing a ‘guarantee’ relating to the performance of the technology.
The guarantee may relate to one or more outcomes of treatment. These could include for
instance (a) clinical outcomes, (b) humanistic or quality of life outcomes, (c) resource use
(for example, a reduction in hospitalisations), (d) financial outcomes (for example, a
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reduction in the amount spent treating a condition), and (e) economic outcomes (for
example, the achievement of a particular cost effectiveness threshold).
As the pressure on health care budgets intensifies and the cost of some of the more
novel treatment remains high, it is likely that the use of risk sharing agreements will
intensify in the future. This may be on two fronts: first, in terms of admitting new
treatments onto national formularies and, second, in terms of enabling faster uptake.
Enabling innovative pricing solutions, e.g. through pilot schemes making selected innovative
medicines available for time-limited periods, or through patient-specific franchise schemes,
could contribute to faster access and uptake of new therapies. This would have particular
application in the case of oncology due to the limited number of patients.
7.5.4. Minimising (negative) externalities
Significant benefits can be gained if key negative externalities were minimised or
altogether eliminated. Such negative externalities often emerge from international price
referencing and comparisons as well as exchange rate differentials and currency
depreciations or appreciations.
7.5.5. Continuous evaluation of oncology drugs
Although ex-ante evaluation provides manufacturers with the incentive to invest in
gathering the evidence that the health service requires to make approvals and also
encourage innovation in areas/therapies where a substantial clinical benefit can be
demonstrated, one drawback of the use of ex-ante as opposed to ex-post evidence is that
there will be uncertainty surrounding the cost-effectiveness of the treatment outside the
RCT setting at the time of launch.
Ex-post evidence is, nevertheless, as crucial as ex-ante evidence in proving the value of a
new treatment. In order to enable this, there needs to be acceptance of data obtained in
naturalistic settings and methodologies on how best to extract value from such data need to
be strengthened. Ownership of such data is also important, as the cost associated with
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gathering such evidence is substantial and creating this evidence should provide the scope
for collaboration between the payer community and manufacturers.
7.5.6. Optimizing resource allocation in health care
The way resources are allocated does not necessarily guarantee their optimal use. There
may be cases of resource misallocation, which could potentially lead to waste and might
also affect access to care. Even if we accept that health care resource allocation operates in
silos, then evidence shows that even the pharmaceutical budget can be further optimised.
In order to do this further focus is needed on the demand-side and the behaviour of
clinicians, and, very importantly, on the use of information systems in real time, both by
payers as well as providers. It is also important to measure the performance of systems in
general and of different policies in particular. Any efficiency savings emerging should be reallocated and re-invested with a view to improving health care services and patient quality
of care.
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